KR101924391B1 - Performance evaluation device and method of superconducting coil for high temperature superconducting rotating machine - Google Patents

Abstract

The present invention relates to a performance evaluating method of a superconductive coil for a high-temperature superconducting rotator capable of evaluating electromagnetic, thermal, and mechanical performances of a superconductive coil for a second generation superconducting rotator to evaluate stability of the superconductive coil, prepare a reliability verification method, and evaluate and confirm an upper limit of threshold current or operating current of a superconducting wire for confirming commercialization and manufacturing the superconductive coil. The present invention is provided to freely vary a refrigerant supply setting when a bobbin for cooling the superconductive coil is cooled, and to easily change a current magnitude of an external stator depending on setting control, thereby differently adjusting a magnitude of a time-varying magnetic field applied to the superconductive coil. The present invention is provided to allow the superconductive coil to set and control an evaluating environment which is the same as a real use environment to be used, thereby ensuring performance evaluation reliability of the superconductive coil.

Description

TECHNICAL FIELD The present invention relates to a superconducting coil for high temperature superconducting rotors,

The present invention is to evaluate and evaluate the stability of superconducting coils and to establish reliability and commercialization of superconducting coils and to evaluate the critical currents and the upper limits of operating currents for superconducting coils for the manufacture of superconducting coils, The present invention relates to a method for evaluating the performance of a superconducting coil for a high-temperature superconducting rotating machine.

Generally, superconducting coils are widely used for commercial and research purposes in medical fields such as NMR and MRI, and industrial fields such as superconducting rotors (electric motors, generators).

A conventional superconducting coil testing apparatus tests the current carrying performance of a superconducting coil by a method of testing a current carrying capacity using a part or a reduced model of a coil or a performance test of a generator or a motor in which a superconducting coil is mounted.

However, the method of testing the electrification performance using a part or the reduced model of the superconducting coil has a problem that the superconducting coil does not fully simulate the driving environment used in the motor or the generator.

Also, the method of performing the performance test of the motor or the generator in which the superconducting coil is installed has a problem that the verification result of the desired level can not be obtained unless the three-dimensional electromagnetic field analysis is applied in the simulation analysis.

In summary, a conventional high-temperature superconducting coil is influenced by a time-varying magnetic field generated by a change in current flowing in a three-phase armature winding due to starting or changing of a load in a rotating machine.

This time-varying magnetic field in the transient state acts as a disturbance applied to the second-generation superconducting coil, which causes an AC loss and an eddy current loss in the metal support supporting the superconducting coil. This causes a rise in the operating temperature of the superconducting coil, Resulting in deterioration of thermal stability and performance.

In addition, the three-phase time-varying magnetic field affects the magnetic field distribution of the superconducting coil to lower the critical current characteristic of the high-temperature superconducting coil, thereby failing to energize the operation current for generating the rated output of the rotator.

As described above, conventional superconducting coils are exposed to various thermal, electromagnetic, and mechanical problems when they are applied to the actual use environment after fabrication. However, there is no apparatus that can accurately evaluate performance of such superconducting coils in advance.

However, in the recent academic and related industries, there are some devices for evaluating the performance of various types of superconducting coils. However, the reliability of the superconducting coils evaluated for the different application environment and the performance evaluation environment is very low It is difficult to use the superconducting coil in a practical manner, and the problem of difficulty in applying the superconducting coil to the superconducting coil is continuously generated.

1. Korean Registered Patent No. 10-1349362 (Registered on April 21, 2014)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems described above, and it is an object of the present invention to provide a method of evaluating stability of a superconducting coil, establishing a reliability verification method, and evaluating a critical current or an upper limit of the operating current of a superconducting wire The present invention provides a method for evaluating the performance of a superconducting coil for a high-temperature superconducting rotating machine, which is capable of accurately evaluating the electromagnetic, thermal, and mechanical performance of a superconducting coil for a second-generation high-temperature superconducting rotor.

The present invention provides a bobbin for cooling a superconducting coil so that the setting of the coolant supply during cooling can be freely varied (the chiller or the coolant circulation module can freely change the coolant supply setting during cooling of the superconducting coil through the bobbin So that the magnitude of the time-varying magnetic field applied to the superconducting coil can be adjusted differently by making it possible to freely change the voltage and current magnitude of the external stator according to the setting control, It is an object of the present invention to provide an evaluation environment that is the same as an actual use environment in which a superconducting coil is to be used, thereby providing a highly reliable performance evaluation of the superconducting coil.

In order to achieve the above object, the present invention provides a method of evaluating the performance of a superconducting coil for a high-temperature superconducting rotor, comprising the steps of rotating a stator 500 of a rotating machine and a rotor 100 The structure of the flux damper 800 is located between the superconducting coil 200 and the stator 500 where the three-phase armature winding 400 is located, and the superconducting coil 400, So that it is possible to evaluate the performance.

The superconducting coil 200 is formed so as to measure the flux and electromotive force of the three-phase armature winding 400 located in the stator 500 using the superconducting coil for one pole field, do.

In addition, the stator 500 of the rotating machine is configured to allow power to be inputted to the armature through a three-phase power slip ring or an independent exciter, and the stator 500 having the three-phase armature winding is connected to a stator- , It is possible to remove the accessories for cooling the rotor by making it possible to perform the characteristics evaluation while the rotor with the superconducting coil is stopped so that the reliability can be improved by simplifying the structure of the characteristic evaluation device .

The performance evaluating apparatus of the present invention may include a superconducting coil 200 mounted symmetrically on one side and the other side of the inner periphery of the rotor 100 that is rotating in the axial direction along the circumferential direction, The Hall sensor 210, the temperature sensor 220 and the strain gauge 230 for measuring the structural deformation amount are formed on the outer circumferential surface of the superconducting coil 200 so that the magnetic field and the temperature distribution characteristic can be grasped. A bobbin 300 is formed at an end of the superconducting coil 200 to support the superconducting coil and the bobbin 300 is connected to the superconducting coil 200 by a separate refrigerator or a coolant circulation module 310 provided on the inner side or the side, The refrigerator and the coolant circulation module 310 are configured to freely change the coolant supply setting during cooling of the superconducting coil 200 through the bobbin, Phase armature winding 400 is formed on the outer circumferential surface of the rotor 100. The three-phase armature winding 400 generates a three-phase time-varying magnetic field, Phase alternating-current power supply 600, and the three-phase alternating-current power supply 600 is configured to be able to adjust the magnitude and frequency of the voltage and current of the three-phase armature winding 400 The superconducting coil 200 under the time-varying magnetic field is formed so that the performance can be evaluated in the same environment as the actual use environment.

The superconducting coil 200 is impregnated with the liquid coolant injected into the rotor 100 from the outside, and is formed so as to perform direct heat exchange between the coolant and the superconducting coil 200.

The cooling jacket 240 is formed on the outer circumferential surface of the superconducting coil 200. The cooling jacket 240 uniformly distributes the solid coolant having a large heat capacity to maintain a stable operation temperature even in a thermal disturbance .

When the refrigerant circulation module 310 is used, the bobbin 300 is formed to be branched in the shape of a tube with respect to the transfer pipe 313, and the injection pipe 311 and the discharge pipe 312, which are parallel cooling channels, The injection pipe 311 and the discharge pipe 312 are connected to the external refrigerant generating device 314 and the cryogenic pump 315 to control the operation temperature .

In addition, the superconducting coil 200 has a heater member 250 installed on the outer circumferential surface of the superconducting coil 200. The superconducting coil 200 can generate a local quench by applying an energy of an operating temperature margin value for a predetermined time, and then test the thermal performance.

As described above, according to the present invention, it is possible to evaluate the characteristics according to the position between the stator and the rotor of the rotating machine by allowing the rotors equipped with the HTS coils to be rotatable. A damper is disposed between the superconducting coils and the stator, It is possible to evaluate the performance of high-temperature superconducting coils according to the presence of the structure, and it is possible to change the operating temperature and current through the external cooling device connected to the superconducting coil and the DC power device, There is an effect that can be freely changed when the magnetic field is generated.

The present invention also relates to a hybrid refrigerant cooling system using gas and liquid refrigerant systems (impregnation cooling system for superconducting coils and bobbin conduction cooling system for superconducting coils), conduction cooling system using cryogenic freezer, and liquid and solid refrigerant at the same time And the stator located outside the rotor has the effect of enabling the evaluation of the thermal and electrical characteristics of the superconducting coil on which the external time-varying magnetic field is applied.

In addition, the present invention makes it possible to repeatedly perform the cooling characteristics from the normal temperature to the operating temperature in the state where the external time-varying magnetic field is applied, thereby making it possible to perform reliable performance evaluation and to determine whether or not reliable operation is possible even when the operating temperature rises It is possible to repeatedly perform the thermal disturbance performance test by inserting the heater into the periphery of the superconducting coil.

Accordingly, the present invention can simulate various operating temperature environments by applying various candidate cryogenic refrigerants that can be used in the case of the hybrid refrigerant cooling system, and it is also possible to use a conduction cooling system by a cryogenic freezer to control the high temperature superconducting field coil Temperature, and mechanical characteristics of a high-field superconducting field coil, including DAQ equipment associated with magnetic fields, temperature sensors, and strain gauges.

In addition, the present invention can reliably evaluate the performance of a superconducting coil for rotor field winding in consideration of the actual operating environment of temperature, current, and magnetic field affecting normal operation, and has a working temperature of 1.8 to 300 K, a degree of vacuum of 10 ^-7 Torr or more There is a sustainable effect.

FIG. 1 and FIG. 2 show an example of a method of evaluating the performance of a superconducting coil according to the present invention,
FIG. 3 is another example of a superconducting coil performance evaluation apparatus according to the present invention,
FIGS. 4 to 5 are enlarged views of a part of the apparatus according to FIG. 3,
Fig. 6 is an exemplary front view of Fig. 3,
7 is an enlarged sectional view of the main part of Fig. 6,
8 is a view illustrating a state where the superconducting coil according to the present invention is coupled to the bobbin.
9 to 10 are schematic views showing a state in which the superconducting rotor is connected to other facilities.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the accompanying drawings.

As shown in FIGS. 1 to 10, the present invention provides a method for evaluating the stability of a superconducting coil, a method of verifying reliability thereof, and a superconducting coil for commercialization. To a performance evaluation method using an evaluation apparatus capable of evaluating electromagnetic, thermal, and mechanical performance of a coil.

The present invention relates to a method of evaluating the performance of a superconducting coil for a HTS superconducting rotor, comprising the steps of: rotating the superconducting coil 200 mounted on the rotor 100 while rotating the superconducting coil 200 according to a position between the stator 500 and the rotor 100; The structure of the flux damper 800 is positioned between the superconducting coil 200 and the stator 500 where the three-phase armature winding 400 is positioned so that the performance of the superconducting coil can be evaluated according to the presence of the structure. .

That is, as shown in FIG. 1, in the case of a high-temperature superconductor, the present invention has anisotropy with respect to an external magnetic field, and its performance, that is, the magnitude of a critical current varies depending on the angle of an external magnetic field incident on the tape- .

At this time, the rotor is rotated by an electric motor 900 coupled to the rotor shaft on one axis, that is, rotated by an angle at which the rotor is positioned in the circumferential direction from the reference angle (0 DEG) It is possible to evaluate the performance change with respect to the magnetic field generated by the armature of the superconducting coil mounted on the rotor by generating the angle difference?

Also, the flux damper structure is a structure for reducing the influence of the magnetic field applied to the high-temperature superconductor described above, and evaluates the performance of the superconducting coil according to the presence or absence of the flux damper structure.

The superconducting coil 200 is formed so as to measure the flux and electromotive force of the three-phase armature winding 400 located in the stator 500 using the superconducting coil for one pole field, do.

That is, as shown in FIG. 2, the present invention uses a rotor 900 for a rotor connected to a rotor shaft to rotate a field superconducting coil at a constant speed to measure a flux and an electromotive force that are linked to the armature winding, And the output characteristics of a rotating machine equipped with a superconducting field winding can be evaluated.

In addition, the stator 500 of the rotating machine is configured to allow power to be inputted to the armature through a three-phase power slip ring or an independent exciter, and the stator 500 having the three-phase armature winding is connected to a stator- , It is possible to remove the accessories for cooling the rotor by making it possible to perform the characteristics evaluation while the rotor with the superconducting coil is stopped so that the reliability can be improved by simplifying the structure of the characteristic evaluation device .

At this time, the stator rotation prime mover is formed such that a plurality of clamps 110 branched on the basis of the movable chuck 1200 can rotate in the circumferential direction while clamping the stator.

2, in order to evaluate the output characteristics of the superconducting rotating machine, the rotor having the superconducting winding for field winding must be rotated at a constant speed to measure the electrical output to be connected to the stationary armature winding do.

However, this structure has a problem that the reliability and economical efficiency of the performance evaluation apparatus are deteriorated by adding an additional accessory device and structure necessary for cooling the rotating superconducting field winding.

That is, in the case of conduction cooling using a cryogenic freezer, an additional slip ring structure is required for power supply to the refrigerator, and in the case of cooling by forced circulation of the refrigerant, a fluid seal for supplying refrigerant into the rotating rotor is required.

In other words, the present invention focuses on a rotating electrical machine structure mainly used in a DC machine, and mechanically rotates a stator where a three-phase armature winding is placed, and efficiently outputs the output characteristics of the super- .

Accordingly, the present invention is configured to include a superconducting coil 200 mounted symmetrically on one side and the other side of the inner circumferential surface of the rotor 100, which rotates in the circumferential direction.

This superconducting coil is mounted on one surface of the cooling bobbin 300 and is formed so as to be close to the three-phase armature winding of the stator. The bobbin is formed to be supported and fixed by a support 700 having a triangular-pyramidal cross-section with respect to a central axis.

The Hall sensor 210, the temperature sensor 220, and the strain gauge 230 for structural strain measurement are formed on the outer circumferential surface of the superconducting coil 200 (see FIG. 3)

These hall sensors, temperature sensors, and strain gauges may be partly different in position depending on the shape of the designed superconducting coil.

A bobbin 300 is formed on the bottom surface of the superconducting coil 200 to cool the superconducting coil while supporting the superconducting coil.

At this time, the bobbin 300 is formed so as to cool the superconducting coil 200 by a conduction method by a separate refrigerator or a refrigerant circulation module 310 provided on the inner side or the side of the bobbin 300.

Accordingly, the refrigerator or the coolant circulation module 310 is formed to be able to freely vary the coolant supply setting during cooling of the superconducting coil 200 through the bobbin, so that the operation temperature can be easily controlled.

At this time, a stator 500 having a three-phase armature winding 400 is formed on an outer circumferential surface of the rotor 100, and the three-phase armature winding 400 is provided with a current supply 3 for generating a three- Phase AC power supply 600 (see FIG. 9).

That is, the three-phase AC power supply device is a power supply device for driving the superconducting motor, as shown in FIG. 7, as an inverter for HTS machine, and a dynamometer power supply device as an inverter for dynamometer.

Accordingly, the three-phase AC power supply 600 is configured to be able to adjust the voltage, current magnitude, and frequency of the three-phase armature winding 400 so that the superconducting coil 200 under the time- So that the performance can be evaluated.

The superconducting coil 200 is impregnated with a gas or liquid coolant injected into the rotor 100 from the outside, and is formed so as to perform direct heat exchange between the coolant and the superconducting coil 200.

The cooling jacket 240 is formed on the outer circumferential surface of the superconducting coil 200. The cooling jacket 240 uniformly distributes the solid coolant having a large heat capacity to maintain a stable operation temperature even in a thermal disturbance .

When the refrigerant circulation module 310 is used, the bobbin 300 is formed to be branched in the shape of a tube with respect to the transfer pipe 313, and the injection pipe 311 and the discharge pipe 312, which are parallel cooling channels, The injection pipe 311 and the discharge pipe 312 are connected to an external refrigerant generating device 314 and a cryogenic pump 315 to control the variable operating temperature And is capable of supplying and recovering refrigerant (see FIG. 9).

9, the external refrigerant producing apparatus 314 corresponds to a compressor and a cryo-cooling system, and the cryogenic pump 315 is installed in a cryo-cooling system, The principle is that after the superconducting motor is cooled, the heated refrigerant is returned to the cryo-cooling system, re-cooled, and then re-introduced into the superconducting rotor, where the cryogenic pump 315 is formed to forcibly circulate the refrigerant.

In addition, the superconducting coil 200 has a heater member 250 installed on the outer circumferential surface of the superconducting coil 200. The superconducting coil 200 can generate a local quench by applying an energy of an operating temperature margin value for a predetermined time, and then test the thermal performance.

FIG. 3 is a schematic diagram of a second-generation superconducting coil performance evaluating apparatus. The superconducting coil 100 is formed by winding a second-generation high-temperature superconducting wire in a pancake form.

Accordingly, the injection pipe 311 and the discharge pipe 312 of the cooling channel are cooled by the hybrid refrigerant cooling method using the external refrigerant (gas and liquid refrigerant) and the solid refrigerant inside the rotor as the forced refrigerant circulation channel.

That is, when the bobbin is cooled by the gas and liquid refrigerant flowing through the refrigerant circulation channel, the superconducting coil is mainly cooled by the conduction method.

Further, a three-phase armature winding 400 is positioned on the inner circumferential surface of the stator 500 (machine shield) to grasp the characteristics of the field coil by an external time-varying magnetic field, and a three- The feeder is connected.

In this case, the 3-phase AC power supply can evaluate the performance of the high-temperature superconducting coil under a time-varying magnetic field having various sizes and frequencies by adjusting the voltage and current as well as the applied frequency.

Then, after superconducting coils are charged with the target operating current in the state where the superconducting coils are cooled to the target operating temperature or less, a three-phase alternating current is applied to the three-phase armature windings to generate a rated alternating magnetic field and a time- do.

Therefore, the injection pipe and the discharge pipe of the cooling channel are arranged in such a manner as to circulate through the bobbin supporting the superconducting coil, and connected to the external refrigerant generator and the cryogenic pump to perform the function of injecting and discharging the refrigerant corresponding to the operation temperature (Cryogenic Refrigerant Application Standard)

At this time, the stator 500 (machine shield) is formed to prevent the time-varying magnetic field of the armature winding from leaking to the outside, and the structure is formed by stacking the electrical steel sheets. This is to reduce the eddy current loss generated in the machine shield.

Also, a damper structure is positioned between the superconducting coil and the stator where the three-phase armature winding is located, so that the performance of the superconducting coil can be evaluated according to the presence or absence of the structure.

At this time, the rotor equipped with the superconducting coil is made rotatable so that the physical angle between the stator and the rotor of the rotor is changed so that the characteristics of the superconducting coil can be evaluated by the angle at which the external time-varying magnetic field is applied.

In order to determine whether reliable operation is possible even when the operating temperature rises due to thermal disturbance, a heater is inserted into the periphery of the superconducting coil, and energy equivalent to the operating temperature margin (e.g.,? T = 5 or 10 K) To generate a local quench and then to test the thermal performance.

In order to evaluate the performance of the superconducting coil at various operating temperatures, the external refrigerant generator is formed to adjust the operating temperature of the superconducting coil in the range of 1.8 to 300 K (room temperature) by adjusting the temperature of the cryogenic coolant in the heat exchanger.

In addition, a liquid refrigerant impregnation method (cryogen batch method), which is capable of direct heat exchange between the refrigerant and the superconducting coil by impregnating superconducting coils into the gas or liquid refrigerant injected into the rotor from the outside, can be applied.

Further, since the cooling jacket corresponding to the shape of the superconducting coil is installed around the superconducting coil, the solid coolant having a large heat capacity is distributed to maintain the operating temperature stably in the thermal disturbance, thereby improving the thermal / electrical stability of the field coil Respectively.

In addition to the cooling method using gas and liquid refrigerant, a conduction cooling or cryogen-free method which can heat-exchange by direct connection between the superconducting coil and the cryogenic freezer is also applicable.

At this time, the superconducting coil is provided with a conduction plate for heat exchange with a material having a high thermal conductivity to improve the heat exchange performance. The temperature of the cryogenic freezer is varied (1.8 to 300 K) It is desirable to be able to evaluate the performance of the apparatus.

In the present invention, a hall sensor, a temperature sensor, and a strain gauge capable of measuring a structural strain amount are attached to each important part of a superconducting coil to detect magnetic field and temperature distribution characteristics, and an electrical signal to each sensor is measured System (DAQ equipment) can be measured in real time and can be characterized.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

100 ... rotor 200 ... superconducting coil
210 ... Hall sensor 220 ... Temperature sensor
230 ... strain gauge 240 ... cooling jacket
250 ... heater member 300 ... bobbin
310 ... chiller or refrigerant circulation module 311 ... injection tube
312 ... discharge pipe 313 ... transfer pipe
314 ... refrigerant generator 315 ... cryogenic pump
400 ... 3 phase armature winding 500 ... stator
600 ... three-phase ac power supply 700 ... support
800 ... flux damper

Claims (3)

The rotor 100 mounted with the superconducting coil 200 is rotatable while the characteristics of the rotor according to the position between the stator 500 and the rotor 100 can be evaluated and the superconducting coil 200 and the three- A method for evaluating performance of a superconducting coil for a high-temperature superconducting rotating machine in which a structure of a flux damper (800) is located between stator (500) where an armature winding (400)
The superconducting coil 200 is formed so as to perform the performance test of the rotor by measuring the flux and the electromotive force of the three-phase armature winding 400 located in the stator 500 using the superconducting coil for one pole field, The stator 500 of the rotating machine is designed to allow power to be applied to the armature through a three-phase power slip ring or an independent exciter. The stator 500, in which the three-phase armature winding is located, It is possible to remove the accessories for cooling the rotor by allowing the rotor to be evaluated in a state where the rotor with the superconducting coil is stopped so that the reliability of the rotor can be improved And the rotor 100 is rotated in the circumferential direction from the reference angle (0 DEG) as a starting point by the motor 900 for the prime mover connected to the rotor shaft uniaxially The rotor is rotated at an angle at which the electrons are positioned to generate a difference ([theta] [deg.] Between the reference angle and the position angle of the rotor so as to evaluate the performance change with respect to the magnetic field generated by the armature of the superconducting coil mounted on the rotor, The superconducting coil 200 is mounted on one surface of the bobbin 300 for cooling the superconducting coil 200 so that the superconducting coil 200 is installed symmetrically on one side and the other side of the inner circumferential surface of the rotor 100 rotating in the circumferential direction. The bobbin is formed to be supported and fixed by a supporter 700 having a triangular-pyramid shape in cross section with respect to the central axis, and the superconducting coil 200 has a magnetic field and a temperature distribution characteristic on the outer circumferential surface thereof A hole sensor 210, a temperature sensor 220 and a strain gauge 230 for structural strain measurement are formed on the bobbin 300. The bobbin 300 is used for the refrigerant circulation module 310 A parallel cooling channel 311 and a discharge pipe 312 are formed so as to branch in the form of a branch with respect to the transfer pipe 313 so as to form a bobbin and a coolant supply and recovery line to cool the superconducting coil 200 The injection pipe 311 and the discharge pipe 312 are connected to the external refrigerant generator 314 and the cryogenic pump 315 so that the operation temperature can be varied and the refrigerant can be supplied and recovered. A method for evaluating the performance of superconducting coils for high temperature superconducting rotors.
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