KR20190041572A - Superconductive cable system using multiple pressure regulating apparatus - Google Patents

Abstract

The present invention provides a superconductive cable system using a multi-pressure control apparatus. According to an embodiment of the present invention, the superconductive cable system using a multi-pressure control apparatus comprises: a liquid nitrogen cooling device to cool liquid nitrogen; a circulation unit arranged on a rear end of the liquid nitrogen cooling device to circulate liquid nitrogen to a superconductive cable system; a first termination connection unit arranged on a rear end of the circulation unit to allow one end of a superconductive cable to be connected thereto; a second termination connection unit connected to the other end of the superconductive cable whose one end is connected to the first termination connection unit; a liquid nitrogen return path connected to the second termination connection unit to form a liquid nitrogen circulation path; a normal pressure control device which is connected to the liquid nitrogen return path, is arranged on a front end of the liquid nitrogen cooling device, and controls a pressure of liquid nitrogen in the superconductive cable system during a normal operation; and an excessive pressure control device which is constructed in parallel with the normal pressure control device, is arranged on a front end of the liquid nitrogen cooling device, and controls a pressure of liquid nitrogen in the superconductive cable system when a fault current of a design value or higher flows thereinto.

Description

TECHNICAL FIELD [0001] The present invention relates to a superconducting cable system using a multi-

The present invention relates to a superconducting cable system using a multiple pressure regulating device, and more particularly, to a superconducting cable system using multiple pressure regulating devices, and more particularly to a superconducting cable system in which a pressure regulating device for controlling liquid nitrogen pressure in a superconducting cable system is multi- To a superconducting cable system using a multi-pressure regulator capable of preventing mechanical damage of the system by rapidly adjusting the superconducting cable.

Generally, a superconducting cable is a power cable using a superconducting phenomenon in which electrical resistance disappears ideally at a cryogenic temperature of minus 196 ° C. In order to maintain the superconducting phenomenon, liquid nitrogen retained at a cryogenic temperature is used as a refrigerant. Therefore, liquid nitrogen must be recirculated to the cooling unit by external heat input and AC loss caused by small amount of cable compared to ordinary cable. The liquid nitrogen is impregnated into the insulation portion of the cable to maintain the insulation performance. The higher the pressure of the liquid nitrogen, the better the insulation performance and the higher the vaporization point of the liquid nitrogen.

In a superconducting cable, when a large current such as a fault current is input, a quench phenomenon occurs in which the superconducting characteristic is lost. The breakdown current is then passed through a copper conductor called a former in the superconducting cable. At this time, a heat is generated according to the resistance component of the copper conductor. When the temperature exceeds the liquid nitrogen vaporization temperature, the liquid nitrogen vaporizes instantaneously and the pressure increases by several tens of times It may cause mechanical damage to the entire system including the superconducting cable. Therefore, the cross sectional area of the formers should be calculated so as not to generate heat at the vaporization temperature of the liquid nitrogen even if the fault current of the designed value is input, and the pressure of the liquid nitrogen should be kept constant above the designed value.

Based on these characteristics, the superconducting cable system consists of a superconducting cable, a liquid nitrogen cooling device, a liquid nitrogen circulation device, and a liquid nitrogen pressure regulating device.

1 is a schematic diagram of a conventional superconducting cable system.

Referring to FIG. 1, a conventional superconducting cable system includes a liquid nitrogen cooling apparatus 10 for cooling liquid nitrogen, a circulation unit 20 for circulating liquid nitrogen to the superconducting cable system provided at the downstream of the liquid nitrogen cooling apparatus 10, A first end connection unit 30 provided at a rear end of the circulation unit 20 and coupled with another power facility and serving as a terminal of the superconducting cable, a superconducting cable 40 connected to the end connection unit, A liquid nitrogen return path 60 connected to the second end connecting portion to constitute a liquid nitrogen circulation path, and a liquid nitrogen return path 60 connected to the liquid nitrogen return path 60 and serving as a liquid nitrogen cooling apparatus 10) and a normal pressure regulating device 70 for regulating the pressure of liquid nitrogen in the superconducting cable system in a normal operation state.

The liquid nitrogen pressure regulator of the conventional superconducting cable system is configured to maintain the system pressure within the maximum and minimum pressure ranges in a steady state. have. Therefore, when a fault current exceeding the expected value such as a wide-range fault is inputted, the liquid nitrogen is heated to a temperature higher than the liquid nitrogen gasification temperature due to the limit of the sectional area of the formers, so that liquid nitrogen may vaporize quickly and cause a serious accident. In order to prevent such a large-scale accident, it is considered to construct a separate line for bypassing the fault current or to additionally use a fault current limiting device, but this is costly and the fault current limiting device There is a problem in safety because the reliability thereof is not sufficiently proved technically.

Japanese Laid-Open Patent Application No. 10-2016-100221

In order to overcome the problems of the prior art, an embodiment of the present invention may further comprise a transient pressure regulator and a pressure regulator selector in a superconducting cable system, so that when a fault current exceeding a predetermined design value flows into the system, To increase the liquid nitrogen pressure and to increase the vaporization point of the liquid nitrogen, thereby preventing the mechanical damage of the system from the expansion pressure caused by the vaporization of liquid nitrogen. Cable system.

According to one aspect of the present invention, there is provided a liquid nitrogen cooling apparatus for cooling liquid nitrogen; A circulation unit provided at a rear end of the liquid nitrogen cooling unit to circulate liquid nitrogen to the superconducting cable system; A first end connection unit provided at a rear end of the circulation unit and connected to one end of the superconducting cable; A superconducting cable connected at one end to the first end connection unit; A second end connection unit to which the other end of the superconducting cable is connected; A liquid nitrogen outlet connected to the second end connection portion to constitute a liquid nitrogen circulation passage; A normal pressure regulator connected to the liquid nitrogen return line and provided upstream of the liquid nitrogen cooling device, for regulating the pressure of liquid nitrogen in the superconducting cable system in a normal operation state; And a transient pressure regulating device connected in parallel with the normal pressure regulating device and connected to the liquid nitrogen return line and disposed upstream of the liquid nitrogen cooling device and configured to regulate the pressure of liquid nitrogen in the superconducting cable system when a fault current exceeding the designed value is inputted .

And a selector connected to the liquid nitrogen return line and provided at a front end of the normal pressure regulating device and the transient pressure regulating device to select the pressure regulating device according to the system condition.

The transient pressure regulating device comprises: liquid nitrogen; A gaseous nitrogen filling part for filling gaseous nitrogen due to vaporization of the liquid nitrogen; And a heater unit for vaporizing the liquid nitrogen with gaseous nitrogen.

The transient pressure regulating device may further include a pressure reducing valve for reducing pressure.

The transient pressure regulator may be applicable to a superconducting cable.

According to one embodiment of the present invention, a superconducting cable system using a multiple pressure regulator can select a cyclic return path of liquid nitrogen as a transient pressure regulator when a fault current above a predetermined design value is introduced into the system, And by increasing the vaporization point of liquid nitrogen, it is possible to prevent the mechanical damage of the system from the expansion pressure due to the vaporization of liquid nitrogen, thereby improving the safety.

1 is a schematic diagram of a conventional superconducting cable system.
2 is a schematic diagram showing a structure inside a superconducting cable constituting a superconducting cable system using a multiple pressure regulator according to an embodiment of the present invention.
3 is a schematic diagram showing a superconducting cable system using a multiple pressure regulator.
4 is a cross-sectional view illustrating an internal structure of a transient pressure regulating device that constitutes a superconducting cable system using a multiple pressure regulator according to an embodiment of the present invention.

The embodiments described below are provided so that those skilled in the art can easily understand the technical idea of the present invention, and thus the present invention is not limited thereto. In addition, the matters described in the attached drawings may be different from those actually implemented by the schematic drawings to easily describe the embodiments of the present invention.

It is to be understood that when an element is referred to as being connected or connected to another element, it may be directly connected or connected to the other element, but it should be understood that there may be other elements in between.

The term "connection" as used herein means a direct connection or indirect connection between one member and another member, and may refer to all physical connections such as adhesion, attachment, fastening, bonding, and bonding.

Also, the expressions such as 'first, second', etc. are used only to distinguish a plurality of configurations, and do not limit the order or other features between configurations.

The singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise. Means that a feature, number, step, operation, element, component, or combination of features described in the specification is meant to imply the presence of one or more other features, A step, an operation, an element, a component, or a combination thereof.

FIG. 2 is a schematic view showing a structure of a superconducting cable constituting a superconducting cable system using a multiple pressure regulator according to an embodiment of the present invention.

2, a superconducting cable 140 used in a superconducting cable system using a multiple pressure regulator according to the present invention generally includes a former 141, a superconducting conductor 142, an insulating portion 143, A shielding portion 144, an inner cryogenic sheath layer 145, and an outer vacuum sheath layer 146. The shape of the superconducting cable is not limited to those shown in FIG. 1, but usually consists of the above elements.

First, the former 141 is generally made of a copper conductor and maintains the shape of the superconducting cable. When the failure current flows into the energization path, the liquid nitrogen is vaporized due to heat generation when a fault current below the designed value is applied. Calculate the cross-sectional area to avoid mechanical damage due to internal pressure build-up.

Then, the superconducting conductor section 142 energizes the load current of the superconducting cable system in a steady state, and uses the superconducting physical phenomenon. If the current that can be energized in the superconducting conductor portion is exceeded, the quenching phenomenon occurs, the superconducting characteristic is lost, the current can no longer be energized, and the excess current flows through the former 141.

The insulating portion 143 is impregnated with liquid nitrogen in the superconducting cable to maintain electrical insulation performance.

The superconducting cable portion 144 is configured to shield the magnetic field of the superconducting cable.

The inner cryogenic sheath layer 145 serves as a storage container for the cooled liquid nitrogen, and maintains the cryogenic temperature of the superconducting cable and the pressure of the liquid nitrogen required for operation of the superconducting cable system. The pressure of liquid nitrogen is related to the insulation performance and the vaporization temperature of liquid nitrogen. The higher the liquid nitrogen pressure, the better the insulation performance and the higher the liquid nitrogen vaporization point.

The outer vacuum sheath layer 146 forms a vacuum and a thermal insulation layer between the inner cryogenic sheath layers 145 to prevent heat penetration into the cooled liquid nitrogen from the outer environment.

FIG. 3 is a schematic view showing a superconducting cable system using a multiple pressure regulator, and FIG. 4 is a view illustrating an internal structure of a transient pressure regulator constituting a superconducting cable system using a multiple pressure regulator according to an embodiment of the present invention. Sectional view.

3 and 4, a superconducting cable system using a multiple pressure regulator according to the present invention includes a liquid nitrogen cooling apparatus 110, a circulation unit 120, a first end connection unit 130, a superconducting cable 140, a second end connection 150, a liquid nitrogen return 160, a normal pressure regulator 170, an overpressure regulator 180, and a pressure regulator selector 190.

First, the liquid nitrogen cooling apparatus 110 cools the liquid nitrogen in the system in order to maintain the temperature for maintaining the superconducting property of the superconducting cable 140.

The circulation unit 120 is provided at the rear end of the liquid nitrogen cooling apparatus 110 to circulate the cooled liquid nitrogen into the system.

The circulation part 120 may be designed as a pump device, but is not limited thereto.

The first end connection unit 130 is provided at a rear end of the circulation unit 120 to couple the superconducting cable 140 and other power facilities and serves as a terminal of the superconducting cable 140.

The superconducting cable 140 is connected to the first end connection unit 130 as a power cable using superconducting characteristics.

The superconducting cable 140 may have a connecting portion in the middle depending on the laying condition, but the present invention is not limited thereto.

The second end connection unit 150 is connected to the superconducting cable 140 and is coupled to another power facility and serves as another terminal of the superconducting cable 140.

The liquid nitrogen return path 160 is connected to the second termination connecting part 150 so that the liquid nitrogen returning path 160 is formed in the entire system of the superconducting cable system except for the first termination connecting part 130, the superconducting cable 140 and the second termination connecting part 150 It constitutes a circulation route of nitrogen.

The normal pressure regulating device 170 is connected to the liquid nitrogen return path 160 and is provided at the front end of the liquid nitrogen cooling device 110.

The normal pressure regulating device 170 maintains the pressure of the system constant within the operating range when a pressure change due to fluctuation of AC loss due to external heat intrusion or current conduction occurs in a normal operation state of the superconducting cable system .

This normal pressure regulating device 170 has the purpose of regulating the liquid nitrogen pressure in the steady state of the superconducting cable system, so that sudden pressure regulation is not required.

The transient pressure regulator 180 is arranged in parallel with the normal pressure regulating device 170 and is connected to the liquid nitrogen return line 160 and is provided at the upstream side of the liquid nitrogen cooling device 110.

The transient pressure regulator 180 is configured to increase the vaporization point of liquid nitrogen by forcibly raising the pressure of the liquid nitrogen when a fault current exceeding the designed value flows into the superconducting cable, It blocks the state of nitrogen vaporization and prevents the mechanical damage of the system.

The operation of the transient pressure regulator 180 is such that when the heater unit 183 first generates heat, the liquid nitrogen 181 which is in contact with the liquid nitrogen 181 is vaporized and the pressure of the gas nitrogen filling unit 182 expands, The liquid nitrogen 181 may be pushed through the liquid nitrogen return line 160 to induce an increase in liquid nitrogen pressure within the cable system, but is not limited thereto. In addition, it is advantageous for the transient pressure regulator 180 to increase the contact area of the liquid nitrogen 181 with the heater and increase the volume of the enclosure to increase the pressure as soon as possible. The heater unit 183 may be operated by receiving the operation signal of the pressure regulator selecting unit 190, but the present invention is not limited thereto. The over-pressure regulator 180 may also be mounted on the top of the housing, further comprising a pressure reducing valve to reduce the overall elevated pressure of the system once the fault current is relieved.

The pressure regulator selecting unit 190 is connected to the liquid nitrogen return line 160 and is provided at a front end of the normal pressure regulating device 170 and the transient pressure regulating device 180 to regulate the pressure regulating device . The liquid nitrogen return line 160 is connected to the normal pressure regulator 170 when the system is in a normal state and the liquid nitrogen return line 160 is connected to the transient pressure regulator 180 when a fault current exceeding the designed value is input Thereby preventing the failure of the superconducting cable system. The operation of the pressure regulator selection unit 190 can be operated by receiving a CT signal for operating the protection relay in the power system. In addition, the operation of the pressure regulator selection unit 190 can be performed by the superconducting shielding It is also possible to drive through a measuring device such as a separate CT or GAUSS meter on the layer, but is not limited thereto.

On the other hand, the transient pressure regulator 180 in the superconducting cable system using the multiple pressure regulator is particularly effective when the system is composed of a superconducting cable having no fault current and current-flow function, but a superconducting cable having a fault current- Even if there is a problem with the Korean Wave function, it can be usefully applied.

The superconducting cable system using the multiple pressure regulating device according to the present invention can operate selectively the normal pressure regulating device 170 and the transient pressure regulating device 180 according to the operation state of the system by the operation of the pressure regulator selecting part 190 Thereby reducing the excessive design of the cross section of the former 141 of the superconducting cable 140. It is also possible to quickly control the liquid nitrogen pressure against the transient state due to the inflow of the fault current exceeding the designed value, It is effective.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, it is to be understood that the above-described embodiments are merely illustrative of the most preferred embodiments of the present invention in order to facilitate understanding of the present invention, and the technical idea of the present invention is limited or limited only by the embodiments It is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities, many of which are within the scope of the present invention. The scope of the present invention is defined by the appended claims rather than the foregoing detailed description, and all changes or modifications derived from the meaning and scope of the claims and the equivalents thereof are included in the scope of the present invention Should be interpreted. It is also to be understood that the inventors have defined terms or words used in the present specification and claims based on the principle that the inventors can properly define the concept of the terms in order to explain their own invention in the best way, It should not be construed as meaning only. In addition, the order of the components described in the above-described process does not necessarily need to be performed in a time-series order, and if the order of operations of the respective components and steps is changed, the process may be included in the scope of the present invention. Of course it is.

110: liquid nitrogen cooling apparatus 120: circulation unit
130: first end connection 140: superconducting cable
141: Former 142: Superconducting conductor section
143: insulation part 144: superconducting shield part
145: internal cryogenic sheath layer 146: external vacuum sheath layer
150: second end connecting portion 160: liquid nitrogen ear
170: normal pressure regulator 180: transient pressure regulator
181: liquid nitrogen 182: gas nitrogen filling part
183: Heater unit 190: Pressure regulator selection unit

Claims (5)

A liquid nitrogen cooling device for cooling liquid nitrogen;
A circulation unit provided at a rear end of the liquid nitrogen cooling unit to circulate liquid nitrogen to the superconducting cable system;
A first end connection unit provided at a rear end of the circulation unit and connected to one end of the superconducting cable;
A superconducting cable connected at one end to the first end connection unit;
A second end connection unit to which the other end of the superconducting cable is connected;
A liquid nitrogen outlet connected to the second end connection portion to constitute a liquid nitrogen circulation passage;
A normal pressure regulator connected to the liquid nitrogen return line and provided upstream of the liquid nitrogen cooling device, for regulating the pressure of liquid nitrogen in the superconducting cable system in a normal operation state; And
A transient pressure regulator connected in parallel with the normal pressure regulating device and connected to the liquid nitrogen return line and provided upstream of the liquid nitrogen cooling device, for regulating the pressure of liquid nitrogen in the superconducting cable system when a fault current exceeding a designed value is inputted;
And a superconducting cable system using the multiple pressure regulator. The method according to claim 1,
Further comprising a selector coupled to the liquid nitrogen return line and provided at a front end of the normal pressure regulator and the transient pressure regulator to select a pressure regulator according to the system condition. . The method according to claim 1,
The transient pressure regulating device includes:
Liquid nitrogen;
A gaseous nitrogen filling part for filling gaseous nitrogen due to vaporization of the liquid nitrogen; And
A heater unit for vaporizing the liquid nitrogen with gaseous nitrogen;
And a superconducting cable system using the multiple pressure regulator. The method according to claim 1,
Wherein the transient pressure regulating device further comprises a pressure reducing valve for reducing the pressure of the superconducting cable. The method according to claim 1,
Wherein the transient pressure regulator is applicable to a superconducting cable.

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