KR100513208B1 - Continuous critical current measurement system for high temperature superconducting tape - Google Patents

Abstract

The present invention is a device for continuously measuring the critical current for each unit length of a long high-temperature superconducting tape, by making the current and voltage terminals variable, so that the measurement distance of the high-temperature superconducting tape can be changed to improve the efficiency of the measurement. In order to increase the height and to increase the contact area of the current terminals, the current terminals are positioned above and below the high temperature superconducting tape. Therefore, even if the current terminal is in contact with air during measurement and the contact is not complete, sufficient contact area can be secured by the lower electrode which is immersed in liquid nitrogen, thereby improving the accuracy of the measurement.

Description

Continuous critical current measurement system for high temperature superconducting tape

The present invention relates to an apparatus for continuously measuring the critical current for each unit length of a long high-temperature superconducting tape.

Bi-2223 superconducting tape attracts attention as the most applicable material to date in superconducting system using high temperature superconductor. In order to apply to the actual system, the length of Bi-2223 superconducting tape is required, and many companies around the world are making great efforts to improve the characteristics.

In general, in order to measure the critical current (Ic) and the critical current density (Jc) of the high-temperature superconducting tape, a four-terminal method of measuring the voltage at the center part while flowing current at both ends of the tape is used. In other words, even though the current flowing through the equation of V = IR, which is the relationship between voltage (V), current (I), and resistance (R), is increased, the voltage becomes '0' without resistance. Since resistance is generated, therefore, the critical current value is measured by measuring the arbitrary voltage value. For this measurement, each terminal of the high temperature superconducting tape is joined by soldering. This soldering method is useful for evaluating the characteristics of short tapes, but the soldering method is not suitable for measuring the characteristics of unit lengths of long tapes. In other words, the soldering is not only time-consuming but also leads to coating defects in the soldering part in subsequent varnish insulation processes due to contamination by the soldering. Therefore, in order to measure the critical current for each unit length of a long tape, a contact critical current (Ic) measuring method for measuring a voltage while flowing a current by physical contact of each terminal should be introduced, not a soldering method.

Therefore, two methods are used as a technique for measuring the critical current for each unit length of the high temperature superconducting tape with respect to the conventional long high temperature superconducting tape, and the measuring principle of these methods is as follows.

First, the critical current of the high temperature superconducting tape is measured in a batch form. The conceptual diagram is shown in FIG. 1. As shown in the figure, the high temperature superconducting tape 1 passes between two high temperature superconducting tape guide rollers 3A and 3B located in the liquid nitrogen container 2. In addition, the high temperature superconducting tape support 4 is used under the high temperature superconducting tape 1 to prevent the tape from falling. In order to measure the critical current by the four-terminal method, four terminals are placed on the high temperature superconducting tape (1) in order of (+) current terminal (5), (+) voltage terminal (6), and (-) voltage terminal (7). ) And (-) current terminals 8 are arranged so that the respective terminals come down from top to bottom to come into contact with the high temperature superconducting tape 1, the current terminals 5 and 8 flow current to the voltage terminals 6 and 7 It is a method of measuring the voltage of the high temperature superconducting tape 1.

The second measuring method is a device for measuring the critical current while continuously sending the tape along the guide roller. 2 is a conceptual diagram of a conventional continuous critical current measuring device. Similar to the method of FIG. 1, the superconducting tape 1 is passed between the superconducting tape guide rollers 9, 10 located in the liquid nitrogen container 2. Here, the guide roller 9 also serves as a (+) current terminal, and the guide roller 10 also serves as a (-) current terminal. In this manner, the high temperature superconducting tape guide rollers 9 and 10 serve not only to transfer the high temperature superconducting tape 1 but also directly to the high temperature superconducting tape 1. Therefore, in order to measure the voltage in the state where the high temperature superconducting tape 1 moves, a separate terminal is required, and the (+) voltage terminal roller 11 and the (-) voltage terminal roller 12 serve as voltage terminals. In order to use the continuous critical current measuring apparatus, the high temperature superconducting tape guide rollers (9,10) are pulled strongly between the high temperature superconducting tape guide rollers (9,10) and the high temperature superconducting tape (1). To increase the contact resistance can be reduced. Thus, this method is suitable for high strength superconducting tapes.

However, the high temperature superconducting tape 1 to date is mostly made of silver (Ag) or a silver alloy, so its strength is weak. Therefore, the continuous critical current measuring device is almost impossible to use due to the characteristics of the high temperature superconducting tape having weak strength, so a batch critical current measuring device should be used.

In addition, in the conventional batch type threshold current measuring device, the critical current Ic can be measured only by contact, and the pressure applied to the current and the voltage terminal becomes an important variable. That is, excessive pressure may cause damage to the high-temperature superconducting tape in the process of applying pressure to secure sufficient contact area at the current terminal for current energization. If the pressure is too low, a measurement error due to contact resistance may occur during current energization. Will be created. In addition, voltage applied too low at the voltage terminal may cause noise in the voltage measurement, too high may damage the high-temperature superconducting tape. Therefore, it is necessary to construct a measuring device that can ensure the accuracy and reliability of the critical current (Ic) measurement.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems. The present invention provides a continuous critical current measuring device of a high temperature superconducting tape capable of accurately measuring a critical current in a contact and non-contact manner by improving a conventional batch type critical current measuring device. The purpose is to provide.

Another object of the present invention is to provide a continuous critical current measuring apparatus of a high temperature superconducting tape capable of suppressing occurrence of noise in damage or voltage measurement of the high temperature superconducting tape by configuring the terminal to adjust the pressure of the current and voltage terminals. I would like to.

It is still another object of the present invention to provide a continuous critical current measuring device of a high temperature superconducting tape that can increase the contact area of a current terminal in contact with the high temperature superconducting tape to improve the measurement accuracy of the critical current.

In order to achieve the above object, the continuous critical current measuring apparatus of the high temperature superconducting tape according to the present invention comprises: a guide roller for transporting the high temperature superconducting tape in a liquid nitrogen container; A high temperature superconducting tape support for supporting a high temperature superconducting tape conveyed in the liquid nitrogen container; In the apparatus for measuring the critical current of the superconducting wire rod having a current terminal and a voltage terminal of the cathode and anode disposed on the high temperature superconducting tape conveyed in the liquid nitrogen container, the current terminal and the voltage terminal is pressure-adjustable The structure is characterized in that the current measuring terminal is installed on the upper surface of the tape support.

The apparatus may further include a transfer unit configured to move the current terminal and the voltage terminal of the negative electrode and the positive electrode disposed on the high temperature superconducting tape in a transfer direction and the reverse direction of the high temperature superconducting tape.

In addition, the current measuring terminal provided on the upper surface of the tape support is preferably located perpendicular to the current measuring terminal disposed on the tape.

In addition, the current terminal and the voltage terminal of the negative electrode and the positive electrode disposed on the high temperature superconducting tape, the pneumatic cylinder for moving perpendicular to the tape; An insulating rod coupled with the pneumatic cylinder; A metal rod and a metal electrode coupled to the insulating rod; It is preferable to comprise a spring for adjusting the pressure at the time of contact of the high temperature superconducting tape and the metal electrode.

In addition, the liquid nitrogen container may further include an induction coil provided in a non-contact manner in a transfer path of the high temperature superconducting tape. In this case, the contact measuring unit for converting the threshold current value measured by the contact method using the current terminal and the voltage terminal into a digital signal; A non-contact measuring unit which converts the eddy current value measured by the non-contact method using the induction coil into a digital signal; Preferably, the control unit further comprises a control unit for storing the measurement data from the contact measuring unit and the non-contact measuring unit in a table. The control unit stores the measured data from the contact measuring unit and the non-contact measuring unit in a table in a predetermined section of the threshold current measurement of the high temperature superconducting tape, and stores the measured data in a storage unit, and then uses the current terminal and the voltage terminal. The contact measurement may be terminated and the eddy current value measured by the induction coil may be controlled to be converted into a threshold current with reference to a table of threshold currents and eddy currents previously stored in the storage unit.

In addition, the apparatus for measuring the continuous critical current of the high temperature superconducting tape according to the present invention is a device for measuring the critical current of the superconducting wire which is conveyed in the liquid nitrogen container, and the induction coil disposed in a non-contact manner with the transfer path of the superconducting wire. ; A storage unit storing the threshold current values of the superconducting wires corresponding to the eddy current values measured by the induction coil in a table form; And a control unit for converting the eddy current value measured by the induction coil into a threshold current with reference to a table stored in the storage unit.

In the continuous critical current measuring device of the high temperature superconducting tape according to the present invention configured as described above, the conventional batch type critical current measuring device was improved to allow simultaneous measurement of the critical current (Ic) by contact and non-contact. . In the present invention, the non-contact critical current (Ic) measurement generally measures the change in the magnetic field due to the generation of eddy currents in the high-temperature superconducting tape when the superconducting wire passes through a region where a constant magnetic field is applied. Since the magnetic field change value is a relative change value and cannot be directly converted into a threshold current, the absolute value of the magnetic field change value may be converted inversely based on the threshold current (Ic) measured value by a contact method.

Therefore, in the present invention, as a device for continuously measuring the critical current for each unit length of a long high-temperature superconducting tape, the critical current Ic can be measured simultaneously in a contact and non-contact manner. In addition to knowing the (Ic) value, at the same time, it is possible to convert the non-contact magnetic field value into the actual threshold current (Ic) value based on this value, thereby eliminating the need to repeat the measurement. Ic) can be measured.

In addition, in the present invention, the current and voltage terminals are configured to be movable in the longitudinal direction of the high temperature superconducting tape so that the measurement interval of the high temperature superconducting tape can be changed to increase the efficiency of the measurement.

In addition, in the present invention, in order to increase the contact area of the current terminal, the current terminals are positioned above and below the high temperature superconducting tape. Therefore, even if the current terminal is in contact with air during measurement and the contact is not complete, sufficient contact area can be secured by the lower electrode which is immersed in liquid nitrogen, thereby improving the accuracy of the measurement.

In addition, in the present invention, the terminal is configured to control the pressure of the current and voltage terminals according to the critical current value of the high-temperature superconducting tape or the strength of the shell silver alloy.

Hereinafter, a continuous critical current measuring apparatus of a high temperature superconducting tape according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

3 is a block diagram of an apparatus for measuring a continuous critical current of a high temperature superconducting tape according to a first embodiment of the present invention.

As shown in the figure, in the first embodiment of the present invention, the high temperature superconducting tape 1 passes between two high temperature superconducting tape guide rollers 3A and 3B located in the liquid nitrogen container 2. . Under the high temperature superconducting tape 1, a high temperature superconducting tape support 40 was used to support the tape. In order to measure the critical current by the four-terminal method, four terminals are placed on the high temperature superconducting tape (1) in order of (+) current terminal (50), (+) voltage terminal (60), and (-) voltage terminal ( 70), when the (-) current terminal 80 is arranged so that each terminal is lowered from the top to come into contact with the high temperature superconducting tape (1), the current terminal (50, 80) flows a current while the voltage terminal (60, In 70), the voltage of the high temperature superconducting tape 1 was measured.

The pair of (+) current terminal 50 and the (+) voltage terminal 60 are made into one pair, and the pair of (-) voltage terminal 70 and the (-) current terminal 80 is made into a pair, respectively, and these are respectively moved by the mover 55. ) And the mover 75, and these movers 55 and 75 are configured to be movable along the rail 90 from side to side, that is, in the longitudinal direction of the high temperature superconducting tape 1. Therefore, the measurement distance interval of the high temperature superconducting tape 1 can be varied, for example, from a minimum of 8 cm to a maximum of 100 cm according to the user's choice.

4 and 5 are shown a detailed view of the terminal capable of pressure control according to the present invention. Pneumatic cylinders 13 and 13 'were used to automatically move up and down the current and voltage terminals 50, 60, 70 and 80. The pneumatic cylinders 13 and 13' were insulated for thermal insulation purposes. Fiber Reinforced Plastics (FRP) rods 15 are coupled, and the FRP rods 15 have copper rods 16 and 16 'and copper electrodes 17 and 17 coupled thereto. Then, pressure adjusting springs 14, 14 'were installed between the brackets 18A, 18B; 18A', 18B 'for the purpose of adjusting the pressure of the high temperature superconducting tape 1 and the contact electrode. The pressure adjusting springs 14 and 14 'may not only change the height of the electrode, but also change the pressure of the electrode by using a spring to apply an appropriate pressure even if the strength and thickness of the high temperature superconducting tape 1 are changed. Designed to be a structure that can be.

6 and 7 show details of the configuration of the high temperature superconducting tape support of FIG. 3. The (+) current terminal (19) and the (+) current terminal (50) and the (-) current terminal (80) are lowered to the high temperature superconducting tape support (40) which touches when pressing the high temperature superconducting tape (1), respectively. The lower (-) current terminal 20 was installed. The lower current terminals 19 and 20 are fixedly coupled to the support 40 by, for example, fixing members 19A to 19D (20A to 20B) such as screws.

Thus, the high temperature superconducting tape 1 is paired with the (+) current terminal 50 and the bottom (+) current terminal 19, and the (-) current terminal 80 and the lower (-) current terminal 20 are paired. By contacting in pairs, it is possible to increase the contact area of the current terminal. In addition, even if the current terminal (50, 80) is in contact with the air during the measurement of the critical current (Ic), even if the contact is not complete, the lower electrode (19) (20), which is immersed in liquid nitrogen and does not occur Sufficient contact area can be secured.

FIG. 8 is a configuration diagram of an apparatus for measuring a continuous critical current of a high temperature superconducting tape according to a second embodiment of the present invention, FIG. 9 is a diagram illustrating a main circuit configuration of the apparatus of FIG. 8, and FIG. 10 is stored in a storage unit in FIG. 9. It is a figure which shows an example of the data table which becomes.

Compared with the apparatus of FIG. 3, the apparatus of the second embodiment has four terminals 50, 60, 70 and 80 and a high temperature superconducting tape guide roller 3B for measuring the critical current Ic by non-contact. Induction coil 18 is configured to be located between. In this way, the actual threshold current (Ic) value of the contact is measured using the current and voltage terminals (50, 60, 70, 80, 19, 20) while the eddy current is measured by non-contact using the induction coil (18). Based on the value, it was possible to convert the actual threshold current (Ic) value.

That is, in the present embodiment, as shown in FIG. 9, in the contact measuring unit 110, the threshold current measured by contact using the current and voltage terminals 50, 60, 70, 80, 19, and 20. Converts (Ic) into a digital signal and transmits it to the control unit 100, and the non-contact measuring unit 110 converts the measured eddy current measured in a non-contact manner using the induction coil 18 into a digital signal and controls the control unit 100. To pass on. In this case, the measured contact critical current Ic and the eddy current measurement value are simultaneously measured and input to the controller 100.

The controller 100 accumulates and stores the input threshold current Ic and the eddy current value in the storage unit 130. As shown in FIG. 10, the data stored in the storage unit 130 has a threshold current value Ic (C1 to Cn) measured in a contact manner and an eddy current value N1 to Nn measured corresponding thereto in a table form. Is stored as.

In the second embodiment of the present invention configured as described above, an extremely long high temperature superconducting tape is simultaneously measured in a contact type and a non-contact type in an initial measurement section, and the measured values are stored in a table in a storage unit, and thereafter, the contact type is not measured. When the corresponding threshold current value is read from the cumulatively stored table for the eddy current value measured in a non-contact manner, the threshold current can be measured in a non-contact manner.

FIG. 11 is a configuration diagram of an apparatus for measuring a continuous critical current of a high temperature superconducting tape according to a third embodiment of the present invention, and FIG. 12 is a circuit diagram of an essential part of the apparatus of FIG.

In the third embodiment, as in the above-described second embodiment, the critical current and eddy current tables shown in FIG. 10, which are tabled by measuring the critical current and the eddy current in a contact and non-contact manner, are stored in the table storage unit 14. to be. In the present embodiment, the non-contact measuring unit 110 converts the eddy current measured value measured in a non-contact manner using the induction coil 18 into a digital signal and transmits the digital signal to the control unit 100, the control unit 100 is a table storage unit ( In 140, the threshold voltage corresponding to the eddy current is output as the threshold current at the corresponding position of the high temperature superconducting tape 1.

13 is a view showing the overall configuration of the apparatus for measuring the continuous critical current of the high temperature superconducting tape according to the present invention.

In the figure, the apparatus according to the first embodiment described above is shown, wherein the supply side winding bobbin 24 and the winding side winding bobbin 25 perform constant speed and variable rotation so that the contact critical current Ic can be measured. The current and voltage terminals 50, 60, 70, and 80 are configured to move left and right on the rail by the movers 55 and 75, and the terminals 50 and 60 as shown in FIGS. , 70, 80) to adjust the pressure. In addition, the current terminals 19 and 20 are additionally disposed on the high temperature superconducting tape support 40 installed on the base 22 to allow the current terminals to contact the high temperature superconducting tape 1 in a double manner, thereby increasing the contact area and measuring stability. Improved.

On the other hand, the present invention is not limited to the above-described typical preferred embodiments, but can be carried out in various ways without departing from the gist of the present invention, various modifications, alterations, substitutions or additions are common in the art Those who have knowledge will easily understand. If the implementation by such improvement, change, replacement or addition falls within the scope of the appended claims, the technical idea should also be regarded as belonging to the present invention.

As described in detail above, according to the present invention, the conventional batch type threshold current measuring apparatus can be improved to accurately measure the threshold current in a contact and non-contact manner. In addition, the terminal may be configured to adjust the pressure of the current and voltage terminals, thereby preventing damage to the high-temperature superconducting tape or noise in voltage measurement. In addition, the measurement area of the critical current can be improved by increasing the contact area of the current terminal in contact with the high temperature superconducting tape. In addition, the current and voltage terminals are configured to be movable in the longitudinal direction of the high temperature superconducting tape so that the measurement interval of the high temperature superconducting tape can be changed, thereby increasing the efficiency of the measurement.

1 is a conceptual diagram of a conventional batch threshold current measuring device.

2 is a conceptual diagram of a conventional continuous critical current measurement device.

3 is a configuration diagram of a continuous critical current measuring device of a high temperature superconducting tape according to a first embodiment of the present invention.

4 and 5 is a detailed view of the terminal pressure control method of the present invention.

6 is a detailed view of the dual electrode configuration of the current terminal.

7 is a block diagram of the high temperature superconducting tape support of FIG.

8 is a configuration diagram of a continuous critical current measuring device of a high temperature superconducting tape according to a second embodiment of the present invention.

9 is a circuit diagram of the apparatus of FIG.

FIG. 10 is a diagram illustrating an example of a data table stored in a storage unit in FIG. 9. FIG.

11 is a configuration diagram of a continuous critical current measuring device of a high temperature superconducting tape according to a third embodiment of the present invention.

12 is a circuit diagram of the apparatus of FIG.

13 is a view showing the overall configuration of the apparatus for measuring the continuous critical current of the high temperature superconducting tape according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: high temperature superconducting tape 2: liquid nitrogen container

3A, 3B: guide roller 4: high temperature superconducting tape support

5: (+) Current terminal 6: (+) Voltage terminal

7: (-) voltage terminal 8: (-) current terminal

9: Guide Roller [Combination of (+) Current Terminal]

10: Guide Roller [Combination of (-) Current Terminal]

11: Roller for (+) Voltage Terminal 12: Roller for (-) Voltage Terminal

13,13 ': Pneumatic cylinder 14,14': Spring for load control

15,15 ': FRP rod for insulation 16,16': Copper rod

17,17 ': copper electrode 18: induction coil

18A, 18B, 18A ', 18B': Bracket 19: Lower (+) current terminal

20: lower (-) current terminal 23: liquid nitrogen

24: supply side winding bobbin 25: winding side winding bobbin

40: high temperature superconducting tape support 50: (+) current terminal

60: (+) Voltage Terminal 70: (-) Voltage Terminal

80: (-) current terminal 100: control unit

110: contact measuring unit 120: non-contact measuring unit

130: storage unit 140: table storage unit

Claims (8)

A guide roller for conveying the high temperature superconducting tape in the liquid nitrogen container; A high temperature superconducting tape support for supporting a high temperature superconducting tape conveyed in the liquid nitrogen container; In the apparatus for measuring the critical current of the superconducting wire having a current terminal and a voltage terminal of the cathode and anode disposed on the high temperature superconducting tape conveyed in the liquid nitrogen container, The current terminal and the voltage terminal of the negative electrode and the positive electrode disposed on the high temperature superconducting tape, A pneumatic cylinder for moving perpendicular to the tape; An insulating rod coupled with the pneumatic cylinder; A metal rod and a metal electrode coupled to the insulating rod; And a spring for adjusting the pressure at the time of contact between the high temperature superconducting tape and the metal electrode, And a current measuring terminal is installed perpendicularly to the current measuring terminal disposed on the tape on an upper surface of the tape support. The method of claim 1, A continuous critical current of the high temperature superconducting tape, characterized in that it further comprises a transfer means for moving the current terminal and the voltage terminal of the negative electrode and the positive electrode disposed on the high temperature superconducting tape in the transfer direction and the reverse direction of the high temperature superconducting tape. Measuring device. delete delete The method of claim 1, And an induction coil installed in the liquid nitrogen container in a non-contact manner in a transport path of the high temperature superconducting tape. The method of claim 5, A contact measuring unit converting the threshold current value measured by the contact method using the current terminal and the voltage terminal into a digital signal; A non-contact measuring unit which converts the eddy current value measured by the non-contact method using the induction coil into a digital signal; And a control unit for storing the measured data from the contact measuring unit and the non-contact measuring unit in a table and storing in a storage unit. The method of claim 6, The control unit stores the measured data from the contact measuring unit and the non-contact measuring unit in a table in a predetermined section in the initial period of the critical current measurement of the high temperature superconducting tape, and stores the stored data in the storage unit. Then, the contact using the current terminal and the voltage terminal End of the equation measurement and control the eddy current value measured by the induction coil to convert to the threshold current by referring to the table of the threshold current and eddy current previously stored in the storage unit. Device. delete