KR20140086483A - Super conducting elecreic power generation system - Google Patents

Abstract

Provided is a superconducting electric power generation system capable of securing high control reliability and simplifying a system configuration by forming a superconducting field coil of a fixing type and disposing a large power converter at not a rotational shaft but an outside of the superconducting electric power generation system. A superconducting electric power generation system according to an embodiment of the present invention includes a superconducting generator including a rotatable armature coil and a fixed superconducting field coil and for outputting a constant voltage without regard to a varying amount of a load; a cryogenic cooling system for cooling the superconducting field coil; an exciter for generating power required in the superconducting generator; and a power converting apparatus fixed to the superconducting generator and an outside of the exciter and for converting the power generated from the exciter into a type required by the superconducting field coil and the cryogenic cooling system to supply the converted power to them.

Description

{SUPER CONDUCTING ELECREIC POWER GENERATION SYSTEM}

The present invention relates to a superconducting power generation system, and more particularly, to a technique for controlling an output voltage of a superconducting power generator using a large capacity power conversion system.

Generally, a superconducting generator means a generator applying superconductivity phenomenon in which electric resistance disappears at an absolute temperature of 0 K, that is, at -273 degrees Celsius. Early superconducting generators use wire materials that generate superconducting phenomena in an absolute temperature range of 4K to 20K. Recently, materials showing superconducting phenomena at relatively high absolute temperatures of 30K to 77K have been found, and development of superconducting generators has accelerated .

Most of the superconducting generators currently developed have a structure in which the superconducting windings replace the copper windings used in the field generators in the superconducting generators. The superconducting windings can be used to form a magnetic field without loss due to electrical resistance. The superconducting generator is more efficient, smaller in size and smaller in weight compared to conventional superconducting generators.

In a typical superconducting generator, when a shaft of a superconducting generator is rotated while a current is supplied to a superconducting field, power is generated in a magnetic field between a field (rotor) of the superconducting generator and the stator, and power is generated from the stator. At this time, the current to be supplied to the superconducting field can be supplied through an external DC power supply or can be supplied through an exciter. When supplied through an exciter, a rectifier is required to convert AC power output from the exciter to DC.

1 is a configuration diagram of a conventional superconducting power generation system.

Referring to FIG. 1, a conventional superconducting power generation system includes a superconducting power generator 10, an exciter 20, a cryogenic cooling system 30, and a power conversion device 40.

The superconducting power generator 10 includes a superconducting rotor 14 using a superconducting field magnet 16 as a winding of a generator and a superconducting stator 12 as a fixed portion assembly including an armature winding at a non- The rotor 14 is rotated and is generated by a magnetic field generated between the superconducting stators 12. The superconducting field 16 is a core part of the superconducting rotor 14, and refers to a superconducting coil that receives electricity from the outside to produce a strong magnet.

The exciter (20) supplies AC power to the superconducting field (16) of the superconducting power generator (10). The exciter 20 is composed of an exciter 22 and an exciter 24 and the exciter 24 is connected to the same shaft 50 as the superconducting rotor 14 of the superconducting generator 10, The exciter 24 and the superconducting rotor 14 are rotated at the same speed as the main shaft by the rotating shaft 50 when the rotating shaft 50 is rotated.

Here, the exciter 22 is a stator, and the exciter 24 is a rotor. The exciter machine 22 may be constituted by a permanent magnet. Therefore, the exciter armature 24 using the permanent magnet generator as a field is rotated by the engine to generate an excitation power source.

The cryogenic cooling system 30 serves to cool the superconducting field 16 by supplying cryogenic coolant to the superconducting rotor 14 of the superconducting power generator 10. The cryogenic cooling system 30 includes a refrigerator for cooling the refrigerant and a refrigerant circulation unit 32 for circulating the refrigerant between the refrigerator and the superconducting rotor 14 of the superconducting power generator 10.

The power conversion device 40 converts the three-phase AC power generated from the exciter 20 into a DC power to be used for the superconducting field 16 of the superconducting power generator 10 and outputs the DC power.

The superconducting power generator 10 uses a very large field magnetic flux, which is a characteristic of the superconducting coil, to reduce the copper loss of the iron loss and the field winding, thereby maximizing the efficiency, so that a very large inductance is obtained. Therefore, in the prior art, such a power conversion device 40 is mounted on the rotary shaft 50 between the exciter 20 and the superconducting rotor 14, so that the power conversion device 40 of large capacity is required for power control of the superconducting power generation system. And there is a limit to the capacity and size of the motor. Further, in the case of the radio control method for controlling the rotating power converter 40, there is a problem that the reliability is lowered in adjusting the output of the exciter 20.

In addition, since the cryogenic cooling system 30 needs to cool the superconducting coils of the superconducting rotor 14 to be cooled, the rotary sealing for the supply of the coolant and the rotary coupling, which is the rotatable coolant supply device, There is a problem that the product cost is increased in the construction. In addition, the conventional cryogenic cooling system 30 requires a circulation pump for cooling and a refrigerant pipe by applying a forced circulation system for conduction cooling. As a result, the system configuration becomes complicated, heat loss due to conduction cooling, There is a problem of.

The present invention has been proposed in order to solve the above problems. It is an object of the present invention to provide a superconducting field coil in which a superconducting field coil is formed in a fixed shape and a large capacity power converter is disposed outside a superconducting power generation system, And it is an object of the present invention to provide a superconducting power generation system that can be simplified.

It is another object of the present invention to provide a superconducting power generation system capable of supplying stable power to a cryogenic cooling system of a superconducting power generation system, preventing heat loss through efficient cooling of the superconducting field coil, and reducing cooling time.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, there is provided a superconducting power generation system including a superconducting power generator including a rotating armature coil and a fixed superconducting field coil, An exciter for generating electric power necessary for the superconducting generator, and a control unit installed in the outside of the superconducting generator and the exciter, for generating electric power generated by the exciter in the superconducting field coil and the cryogenic temperature coil And a power conversion device for converting and supplying the power to the type required by the cooling system.

The superconducting field coil may be formed in the stator of the superconducting power generator.

The power conversion apparatus includes an electric power distributor for distributing AC power generated by the exciter to the superconducting field coil and the cryogenic cooling system and supplying the distributed AC power to the superconducting field coil through an ADD A converter, a resistance load connected in parallel with the superconducting field coil to consume energy generated in the superconducting field coil as heat, and a switch connected in series to the resistance load.

The cryogenic cooling apparatus can cool the superconducting field coil by liquefying the refrigerant according to the operating temperature of the superconducting power generator, recover the vaporized refrigerant, and re-liquefy the refrigerant.

The exciter may include an exciter armature coil provided at the same rotation axis as the armature coil and rotating and a fixed exciter coil.

The superconducting power generation system according to the embodiment may further include a brush for transmitting AC power generated through the armature coil to an external load of the superconducting generator housing.

According to the present invention, a fixed superconducting field coil in a superconducting power generation system and an armature coil in which an exciter output is generated are fixed. In this system, AC power of an exciter is converted into DC power, The device can be fixed to the outside of the system, so that it is excellent in terms of reliability and is easy to maintain and repair.

In addition, the superconducting field coil is mounted on a stator that does not rotate, and it is cooled directly to minimize the heat loss, and the cooling time can be reduced through simultaneous supply of the upper and lower refrigerants. Since both the cryogenic cooling system and the superconducting field coil are fixed, Magnetic fluid seals for rotary sealing and Rotary Coupling, which is a rotary refrigerant supply, are not required, simplifying the configuration of the cryogenic cooling system.

In addition, since the superconducting field current can be controlled by consuming energy by using the parallel resistance load of the power conversion device, it is possible to overcome the high inductance problem of the superconducting coil, and the constant output voltage control in the superconducting power generation system It is possible.

Also, since the cryogenic cooling system, which is essential for the superconducting power generator, can operate itself through the power of the exciter without the external power source, the superconducting power generation system can always maintain the cryogenic state, thereby improving the reliability of the system.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a configuration diagram of a conventional superconducting power generation system. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a superconducting power generation system.
FIG. 3 is a diagram for explaining the power converter of FIG. 2 in more detail; FIG.

The above and other objects, features, and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, which are not intended to limit the scope of the present invention. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a configuration diagram of a superconducting power generation system according to an embodiment of the present invention. FIG. 3 is a diagram for explaining the power converter 400 of FIG. 2 in more detail.

2 and 3, a superconducting power generation system according to an embodiment of the present invention includes a rotating armature coil 120 and a fixed superconducting field coil 110, and a constant voltage A cryogenic cooling system 200 for cooling the superconducting field coil 110, an exciter 300 for generating electric power necessary for the superconducting power generator 100, And a power conversion device 400 that is fixedly installed and converts power generated in the exciter 300 into a form required by the superconducting field coil 110 and the cryogenic cooling system 200 and supplies the converted power.

Further, a brush 500 for transmitting AC power generated through the rotating armature coil 120 to an external load of the housing of the superconducting generator 100, and a magnetic shield 130 for preventing magnetic flux leakage can do.

The superconducting field coil 110 is formed in the stator of the superconducting power generator 100 and may be formed of a superconducting coil wrapped with the superconducting wire. The superconducting field coil 110 generates a magnetic flux by a DC power source and transmits the generated magnetic flux to the armature coil 120 so that electric power is generated when the armature coil 120 rotates. The superconducting field coil 110 is connected to the cryogenic cooling system 200 to maintain cryogenic temperatures.

The armature coil 120 is a rotating armature coil type and generates three-phase AC power using the magnetic flux generated by the superconducting field coil 110. The generated three-phase alternating-current power can be transmitted to the outside of the housing through the brush 500 and transmitted to the external load.

The cryogenic cooling system 200 uses a refrigerant (nitrogen, neon, or the like) suitable for the operating temperature of the superconducting power generation system, and liquefies the refrigerant to cool the superconducting field coil 110. In order to efficiently cool the superconducting field coil 110 and shorten the cooling time, the superconducting field coil 110 is supplied at the same time with a system for liquefying the refrigerant, and the refrigerant vaporized in the heat exchanger is recovered to recover the vaporized refrigerant in the re- And a system for re-cooling the liquid refrigerant to supply and recover it. Further, although not shown, the cryogenic cooling system 200 may further include an additional configuration for cooling and circulating the refrigerant, such as a compressor and a pump.

The exciter 300 includes an exciter coil 320 and a fixed exciter coil 310 disposed on the same axis as the armature coil 120 and rotating. Depending on the cooling load of the cryogenic cooling system 200 and the capacity of the superconducting coil, the capacity of the exciter 300 may be selected at the time of designing the generator, and may be installed as a rotary field type in which power is output from the stator. The exciter coil 310 and the exciter coil 320 may be manufactured by manufacturing a core using a silicon steel plate which is highly practical in terms of cost and by laminating a copper wire. The power applied to the fixed superconducting field coil 110 of the superconducting power generator 100 and the power applied to the fixed cryogenic cooling system 200 can be directly connected without a separate device such as a brush.

The power conversion apparatus 400 includes a power distributor 410 for distributing the AC power generated by the exciter 300 to the superconducting field coil 110 and the cryogenic cooling system 200 and supplying the distributed AC power to the superconducting coil 110 and the cryogenic cooling system 200, An ADD converter 420 for converting the DC power into DC power required for the field coil 110, a resistance load 440 connected in parallel with the superconducting field coil 110 to consume energy generated in the superconducting field coil 110 as heat, And a switch 430 connected in series to the resistive load 440. Here, the power divider 410 may include a circuit for supplying the output voltage of the exciter 300 to the power supply of the cryogenic cooling system 200 and the superconducting field coil 110.

The power conversion apparatus 400 converts the three-phase AC power generated in the fixed armature coil 310 of the exciter 300 into an AC-DC converter using the three-phase full bridge diode circuit in the ADD converter 420 as DC power And converts the converted DC power into a voltage and a current necessary for the superconducting field coil 110 for controlling the constant output voltage of the superconducting power generator 100 in the DC-DC converter. In addition, the parallel resistance load 440 can be configured to consume energy generated in the superconducting field coil 110 as heat.

The brush 500 connects the three-phase alternating-current power output from the armature coil 120 to an external system. The brush 500 is installed on a shaft and is configured to be pulled out of the generator housing for easy maintenance and repair .

The magnetic shield 130 is disposed on the superconducting field coil 110 in order to prevent the magnetic flux generated in the superconducting field coil 110 from leaking to the outside in the course of returning to the field coil 110 again through the armature coil 120. [ And may be cylindrical in outer diameter, and a magnetic material is used as the material.

The foregoing description is merely illustrative of the present invention, and various modifications may be made by those skilled in the art without departing from the spirit of the present invention. Accordingly, the embodiments disclosed in the specification of the present invention are not intended to limit the present invention. The scope of the present invention should be construed according to the following claims, and all the techniques within the scope of equivalents should be construed as being included in the scope of the present invention.

100: superconducting generator 110: superconducting field coil
120: armature coil 130: magnetic shield
200: Cryogenic cooling system 300: Exciter
310: an exciter coil coil 320: an exciter coil coil
400: power converter 410: power divider
420: ADD converter 430: switch
440: Resistive load 500: Brush

Claims (6)

A superconducting generator including a rotating armature coil and a fixed superconducting field coil, the superconducting generator outputting a constant voltage irrespective of the variation of the load;
A cryogenic cooling system for cooling the superconducting field coil;
An exciter for generating electric power necessary for the superconducting generator; And
A power converter installed fixedly to the superconducting generator and the exciter to convert the power generated by the exciter into a form required by the superconducting field coil and the cryogenic cooling system;
And the superconducting power generation system. The method according to claim 1,
Characterized in that the superconducting field coil is formed in the stator of the superconducting generator
Superconducting power generation system. The method according to claim 1,
The power converter
A power distributor for distributing and supplying AC power generated by the exciter to the superconducting field coil and the cryogenic cooling system;
An ADD converter for converting the divided AC power into DC power required for the superconducting field coil;
A resistance load connected in parallel with the superconducting field coil to dissipate heat generated in the superconducting field coil into heat; And
A switch serially connected to the resistive load; Containing
Superconducting power generation system. The method according to claim 1,
Wherein the cryogenic cooling device liquefies the refrigerant according to the operating temperature of the superconducting power generator to cool the superconducting field coil, and recovers the vaporized refrigerant to re-
Superconducting power generation system. The method according to claim 1,
The exciter
An exciter armature coil provided on the same rotation axis as the armature coil and rotating; And
Fixed-type exciter coil; Containing
Superconducting power generation system. The method according to claim 1,
A brush for transmitting AC power generated through the armature coil to an external load of the superconducting generator housing;
The superconducting power generation system further comprising:

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