KR101025836B1 - Superconducting power transforming apparatus - Google Patents

Abstract

The present invention relates to a superconducting power transformer device. The superconducting power transformer according to the present invention is a transformer cable through-hole is formed, the transformer container is filled with the cooling means of the liquid; A superconducting transformer accommodated in the transformer container in the cooling means; A switch cable passage hole is formed, and a switch receiver having a liquid insulating oil filled therein; A voltage tap changer housed in the insulating oil and accommodated in the switch acceptor; The transformer cable tap of the transformer receptor and the switch cable passage of the switch acceptor are connected such that the transformer winding tap cable connecting the superconducting transformer and the voltage tap changer passes from the transformer acceptor and the switch acceptor. It is characterized in that it comprises a closed vacuum cable connector. This ensures the operation of voltage tap changers, such as superconducting transformers operating at cryogenic temperatures and on-load tap changers operating in insulating oil.

Description

Superconducting Power Transformers {SUPERCONDUCTING POWER TRANSFORMING APPARATUS}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a superconducting power transformer device and to a superconducting power transformer device for ensuring the operation of a voltage tap changer such as a superconducting transformer operating at cryogenic temperatures and an on-load tap changer operating in insulating oil.

In general, the term transformer refers to a device that changes the value of alternating voltage or direct current by using electromagnetic induction.In general, a power transformer connected to a power transmission and distribution line is connected to a primary winding connected to a power supply and a load connected to a load. Including the secondary winding, it functions to raise or lower a specific voltage while keeping the power intact.

On the other hand, research on the development of superconducting power devices with no loss of resistance along with the development of superconductors has been conducted in various ways, and has overcome some limitations of the existing low temperature superconductor (LTS) to operate at cryogenic temperatures. The development of High Temperature Superconductor (HTS) has further accelerated the research for the practical use of superconducting power devices, and in response, the superconductor using superconductor (hereinafter referred to as 'superconducting power transformer') Research for commercialization is continuing.

Superconducting power transformers reduce the volume and weight of conventional transformers, and have the advantages of high efficiency, environmental friendliness, and overload resistance. In the early stages of development of superconducting power transformers, energy savings and reduced operating costs due to high efficiency have been recognized as important advantages.

However, in recent years, the weight and size of a superconducting transformer can be reduced to a greater advantage. The standard capacity of three-phase 154 kV class transformers, which are commonly used, is 60 MVA. However, when the load increases in the near future, the capacity increase of the transformer using the existing copper wire leads to an increase in volume, which causes a problem of moving the transformer currently installed in the downtown to a wider place.

As such, the superconducting transformer can not only replace the existing transformer, but also can reduce the size of the existing transformer by 1/3 or 1/2, thereby eliminating the problem that the installation site is restricted by the increase in capacity.

On the other hand, in the case of a general transformer currently in practical use, the secondary voltage (load voltage or low pressure) is ideally maintained at a prescribed rated voltage, but the actual voltage of the transformer is not constant at each installation site. Since the internal voltage drop of the transformer is constantly changing according to the magnitude and power factor of the load current, the secondary output voltage also fluctuates.

Therefore, the secondary voltage should be adjusted close to the rated voltage for the fluctuating load. An on-load tap changer (OLTC), which adjusts the secondary voltage to the rated voltage by changing the winding ratio of the transformer, It is installed and used in a transformer.

As such, the process for adjusting the secondary voltage to the rated voltage in the transformer is also required in the superconducting transformer, and therefore, the on-load tap changer (OLTC) applied to the superconducting transformer is also used for the practical use of the superconducting transformer. Should be considered.

Typical transformers and on-load tap-changers are installed and operated in immersion oil together. However, even if the superconducting transformer is put into practical use, there is a problem in that the existing method of installing the on-load tap-changer with the transformer cannot be applied to the superconducting transformer as it is.

This means that high-temperature superconducting transformers operate at "high temperatures" rather than low-temperature superconducting transformers, and high-temperature superconducting transformers also operate at very low temperatures, much lower than conventional power equipment, so that they can be insulated with on-rod tap changers as in conventional transformers. Cannot be dipped together.

Accordingly, the present invention has been made to solve the above problems, the superconducting transformer and the voltage to ensure the operation of the voltage tap-changer, such as superconducting transformer operating at cryogenic temperature and on-load tap changer operating in insulating oil It is an object of the present invention to provide a superconducting power transformer device that allows a tap-changer to operate in mutually independent operating environments.

According to the present invention, the transformer cable passage is formed, the transformer container is filled with the cooling means of the liquid inside; A superconducting transformer accommodated in the transformer container in the cooling means; A switch cable passage hole is formed, and a switch receiver having a liquid insulating oil filled therein; A voltage tap changer housed in the insulating oil and accommodated in the switch acceptor; The transformer cable tap of the transformer receptor and the switch cable passage of the switch acceptor are connected such that the transformer winding tap cable connecting the superconducting transformer and the voltage tap changer passes from the transformer acceptor and the switch acceptor. It is achieved by a superconducting power transformer device, characterized in that it comprises a hermetically sealed cable connector.

Here, the superconducting transformer is provided in the form of a high temperature superconducting transformer; The liquid cooling means may be provided with liquid nitrogen.

In addition, the voltage tap changer may be provided as an on-load tap changer (OLTC).

Here, a transformer coupling part for coupling with the cable connector is provided in the transformer cable passage of the transformer receptor; The switching cable passage of the OLCT receptor is provided with a switching coupling for coupling with the cable connector; The cable connector is provided with a tubular connector body, a transformer connection portion provided on one side of the connector tube body to be sealably coupled with the transformer coupling portion, and provided on the other side of the connector tube body to seal the switch coupling portion. It may comprise a switching connection that is possibly coupled.

And a transformer sealing wall provided between the transformer coupling part and the transformer connecting part to seal the transformer container and the cable connecting pipe, the transformer sealing wall having a plurality of first cable through holes passing through the transformer winding tab cable; It may further include a switching closure wall installed between the switch coupling portion and the switch connecting portion to seal the switch receptor and the cable connection pipe, the switch sealing wall formed with a plurality of second cable through hole passing through the transformer winding tap cable. .

Here, the plurality of first cable through holes are formed to be spaced apart from each other so that insulation breakdown does not occur between the transformer winding tap cable passing through each of the first cable through holes; The plurality of second cable through holes may be formed to be spaced apart from each other such that insulation breakdown does not occur between the transformer winding tap cables passing through the second cable through holes.

The transformer sealing wall and the switching sealing wall may be made of an epoxy material.

The cable connector may further include a pump connection part to which a vacuum pump for making a vacuum inside the connector body is connected.

According to the present invention, the superconducting transformer and the voltage tap-changer can be operated in a mutually independent operating environment to ensure the operation of the superconducting transformer operating at cryogenic temperature and the voltage tap changer such as the on-load tap changer operating in the insulating oil. A superconducting power transformer device is provided.

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

Superconducting power transformer 100 according to the present invention, as shown in Figure 1, the transformer acceptor 10, the superconducting transformer 30, the switch acceptor 20, the voltage tap changer 40 and the cable connection Tube 50.

Superconducting transformer 30 is composed of a primary side connected to the power source and a secondary side connected to the load, it is configured using a superconductor. Here, the superconducting transformer 30 according to the present invention is an example that a high temperature superconductor (HTS) is used.

The transformer container 10 has a substantially cylindrical shape to accommodate the superconducting transformer 30 therein. In addition, a transformer cable through hole 11 through which the transformer winding tap cable 60 passes is formed at one side of the transformer container 10. In the present invention, as shown in FIG. 1, the transformer cable passage 11 is provided in the lower region of the transformer container 10, and the superconducting transformer 30 and the voltage tap changer 40 are used as an example. Of course, it can be provided in the upper region or the central region according to the arrangement of the transformer winding tap cable 60 to connect.

In addition, inside the transformer receptor 10 is filled with a cooling means of the liquid phase to maintain the cryogenic state during operation of the superconducting transformer 30. Here, in the present invention, the liquid nitrogen is provided as the liquid cooling means to be filled in the transformer container 10 as an example, the liquid cooling means of the other form that enables the operation of the superconducting transformer 30 is applicable. Of course.

On the other hand, the voltage tap changer 40 changes the tap connection of the winding of the superconducting transformer 30 so that a constant voltage can be supplied from the superconducting transformer 30 even when the load changes. In the present invention, an on-load tap changer (OLTC) for changing the tap connection of the winding in the state in which the superconducting transformer 30 is operated as the voltage tap changer 40 is used as an example. Non Load Tab Changer (NLTC) can also be applied.

The switch acceptor 20 has a substantially cylindrical shape to accommodate the voltage tap changer 40 therein. In addition, a switch cable passage opening 21 through which the transformer winding tap cable 60 passes is formed at one side of the switch receiver 20. Here, the switching cable through hole 21 formed in the switch acceptor 20 is a transformer cable through hole 11 so that the transformer cable through hole 11 and the switch cable through hole 21 are connected through the cable connector 50. It is provided at a position corresponding to).

In addition, an insulating oil is formed inside the switch acceptor 20 to cool the voltage tap changer 40. Here, as the insulating oil, it is preferable that a material having a high flash point, a low freezing point, a large fluidity, a large specific heat so as to increase the cooling effect, and that do not form precipitates or oxidize even at low temperatures.

The cable connector 50 is connected to the transformer cable tap opening 11 of the transformer receptor 10 and the converter receptor such that the transformer winding tap cable 60 connecting the superconducting transformer 30 and the voltage tap changer 40 passes therethrough. Connect the switching cable passage (21).

Here, the cable connector 50 according to the present invention is formed in a closed vacuum state from the transformer acceptor 10 and the switch acceptor 20. As a result, the transformer receptor 10 providing the cryogenic operating environment and the switch acceptor 20 providing the low temperature operating environment are mutually independent in space. Operation of the voltage tap changer 40, such as a load tap changer, is ensured.

Hereinafter, the coupling configuration of the transformer acceptor 10, the switch acceptor 20, and the cable connector 50 according to the present invention will be described in detail with reference to FIGS. 2 and 3.

The transformer cable passage 11 of the transformer receiver 10 is provided with transformer coupling parts 12 and 13 for coupling with the cable connector 50. Referring to FIG. 2, the transformer coupling portions 12 and 13 may include a first extension pipe portion 13 and a first extension pipe portion 13 extending outward from the transformer cable passage opening 11 of the transformer container 10. It may include a first coupling skirt portion 12 extending radially outward from the end of the).

In addition, the switching cable passage port 21 of the switch acceptor 20 corresponds to the shape of the transformer coupling portions 12 and 13 of the transformer acceptor 10 for switching with the cable connector 50. Coupling portions 22 and 23 are provided. Referring to FIG. 2, the switch coupling portions 22 and 23 may include a second extension pipe portion 23 extending outward from the switching cable passage opening 21 of the switch receptor 20, and a second extension pipe portion ( And a second engaging skirt portion 22 extending radially outward from the end of 23.

The cable connector 50 may include a tubular connector body 51, a transformer connection part 52, and a switching connector 53. The transformer connection part 52 is provided on one side of the connector body 51 and is hermetically coupled to the transformer coupling parts 12 and 13 of the transformer container 10. Here, the transformer connection portion 52 extends radially outward from one edge of the connector tube body 51 so as to be engageable with the first coupling skirt portion 12 of the transformer coupling portions 12 and 13.

In addition, the switch connecting portion 53 is provided on the other side of the connecting tube body 51 is coupled to the switch coupling portion 22, 23 of the switch acceptor 20 to be hermetically sealed. Here, the switch connecting portion 53 corresponds to the shape of the transformer coupling portion 52, the other side of the connecting pipe main body 51 to be able to engage with the second coupling skirt 22 of the switch coupling portion (22, 23). It is lined up radially outward from the edge.

Here, the superconducting power transformer 100 according to the present invention, as shown in Figures 2 and 3, may include a transformer sealing wall 54 and the switching sealing wall (55).

The transformer sealing wall 54 is installed between the transformer coupling parts 12 and 13 and the transformer connection part 52 and seals the transformer container 10 and the cable connector 50. Here, a plurality of first cable through holes 54a for passing the transformer winding tap cable 60 are formed in the transformer sealing wall 54.

In addition, the switching sealing wall 55 is installed between the switching coupling portions 22 and 23 and the switching connecting portion 53 to seal the switch acceptor 20 and the cable connecting pipe 50. Here, the switch sealing wall 55 is provided with a plurality of second cable through holes 54a for passage of the transformer winding tap cable 60 similarly to the transformer sealed wall 54.

According to the configuration as described above, the transformer coupling portion 12, 13 and the transformer connection portion 52 is bolted in a state where the transformer sealing wall 54 is disposed between the transformer coupling portion 12, 13 and the transformer connection portion 52 The coupling coupling part 22, 23 and the transformer connection part 52 are bolted in a state in which the switching sealing part 55 is disposed between the switching coupling parts 22 and 23 and the switching connecting part 53, respectively. By interconnecting through fastening, the transformer acceptor 10, the cable connector 50, and the switch acceptor 20 are spatially isolated from each other.

Here, the plurality of first cable through holes 54a formed in the transformer sealing wall 54 are transformer winding tap cables 60 passing through the respective first cable through holes 54a, as shown in FIG. 3. It is formed to be spaced apart from each other so that insulation breakdown does not occur. In addition, insulation breakdown between the plurality of second cable through holes 54a formed in the switching sealing wall 55 and the transformer winding tap cable 60 passing through each of the second cable through holes 54a does not occur. So as to be spaced apart from each other.

In addition, the transformer sealing wall 54 and the switching sealing wall 55 may be made of an epoxy material which is advantageous for maintaining the cable connection pipe 50 in a vacuum state, and the transformer sealing wall 54 and the switching sealing wall 55 may be provided. The first cable through hole 54a and the second cable through hole 54a in a state where the transformer winding tap cable 60 passes through the first cable through hole 54a and the second cable through hole 54a formed in the Epoxy finish to maintain sealing.

In the state in which the connection is completed as described above, by connecting the vacuum pump through the pump connection portion formed in the cable connector 50, by removing the air in the connector body 51 of the cable connector 50 to the connector body ( 51) The interior can be vacuumed.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a view showing the configuration of a superconducting power transformer according to the present invention,

FIG. 2 is a view for explaining a coupling state of a transformer receptor, a cable connector, and a switch receptor of the superconducting power transformer of FIG. 1;

3 is a view showing the configuration of the transformer tight wall of the superconducting power transformer according to the present invention.

<Description of Major Numbers in Drawing>

100: superconducting power transformer 10: transformer receptor

11: transformer cable passage 20: switch receptor

21: switching cable passage 30: superconducting transformer

40: voltage tap changer 50: cable connector

51: connector body 52: transformer connection

53: switching connection

Claims (8)

In the superconducting power transformer device, A transformer receiver having a transformer cable passage formed therein and having a liquid cooling means filled therein; A superconducting transformer accommodated in the transformer container in the cooling means; A switch cable passage hole is formed, and a switch receiver having a liquid insulating oil filled therein; A voltage tap changer housed in the insulating oil and accommodated in the switch acceptor; The transformer cable tap of the transformer receptor and the switch cable passage of the switch acceptor are connected such that the transformer winding tap cable connecting the superconducting transformer and the voltage tap changer passes from the transformer acceptor and the switch acceptor. A superconducting power transformer device comprising a cable connection in a sealed vacuum state. The method of claim 1, The superconducting transformer is provided in the form of a high temperature superconducting transformer; The liquid-phase cooling means is a superconducting power transformer, characterized in that provided with liquefied nitrogen. The method according to claim 1 or 2, The voltage tap changer is a superconducting power transformer, characterized in that the on-load tap changer (OLTC) is provided. The method of claim 3, A transformer coupling portion for coupling with the cable connector is provided at the transformer cable passage opening of the transformer receiver; The switching cable passage of the OLTC receptor is provided with a switching coupling for coupling with the cable connector; The cable connector, With the tubular connector body, A transformer connection part provided at one side of the connector tube body to be sealably coupled to the transformer coupling part; A superconducting power transformer device, characterized in that it comprises a switching connection portion provided on the other side of the connector tube body and sealingly coupled to the switching coupling portion. The method of claim 4, wherein A transformer sealing wall installed between the transformer coupling part and the transformer connecting part to seal the transformer container and the cable connector, and having a plurality of first cable through holes passing through the transformer winding tab cable; And a switching closure wall installed between the switching coupling part and the switching connection part to seal the switch receiver and the cable connection pipe, the switching sealing wall having a plurality of second cable through holes passing through the transformer winding tap cable. Superconducting power transformer device. The method of claim 5, The plurality of first cable through holes are formed to be spaced apart from each other such that insulation breakdown does not occur between the transformer winding tap cables passing through the first cable through holes; And the plurality of second cable through holes are formed to be spaced apart from each other so that insulation breakdown does not occur between the transformer winding tap cables passing through the second cable through holes. The method of claim 5, The transformer closing wall and the switching sealing wall is a superconducting power transformer, characterized in that provided with an epoxy material. The method of claim 5, The cable connector, And a pump connection part to which a vacuum pump for making the inside of the connector body into a vacuum state is connected.

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