JP2004335480A - Current lead using oxide superconductor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a current lead using an oxide superconductor which has a small dependency on magnetic field by a mixed phase state of Bi-2223 and Bi-2212 without substituting a part of Bi by Pb or without adding Pb, capable of demonstrating superconducting characteristics as a high temperature phase, capable of obtaining a high temperature superconductor applicable for a current lead or the like in practical level of, for example, a critical current density of 300 A/cm2 at a temperature of 77K. <P>SOLUTION: The current lead uses an oxide superconductor of Bi system containing Sr, Ca, and Cu, and not containing Pb, and the ratio of Bi-2212 composition and Bi-2223 composition is 1-X:X (X=0.4-0.8). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a current lead using an oxide superconductor, and particularly to a Bi-based oxide superconductor, in which a Bi-2223 composition and a Bi-2212 composition are mixed in an appropriate amount under a magnetic field. The present invention relates to a current lead using an oxide superconductor which can improve superconductivity and is applied to a current lead.

  Among the conventional Bi-based high-temperature superconductors, those that can be practically used as current leads, for example, include a Bi-2223 composition called a high-temperature phase and a Bi-2212 composition called a low-temperature phase.

  Bi-2223 includes three elements of Sr, Ca, and Cu in addition to Bi, and has an atomic ratio of Bi: Sr: Ca: Cu = 2: 2: 2: 3.

  Bi-2212 includes three elements of Sr, Ca, and Cu in addition to Bi, and has an atomic ratio of Bi: Sr: Ca: Cu = 2: 2: 1: 2.

  The temperature at which these transition to superconductivity (critical temperature) is about 110K for Bi-2223 in the high-temperature phase and about 80K for Bi-2212 in the low-temperature phase. Conventionally, either composition is made almost single-phase and used as a current lead. We are using.

  That is, in general, the Bi-2212 composition has a critical temperature (Tc) of 80K, which is only slightly higher than the liquid nitrogen temperature (77K). difficult.

  However, at a temperature of 40 K or less, the characteristics under a magnetic field are better than Bi-2223. Therefore, it is desirable to use the current lead of the conventional Bi-2212 at a temperature of 40K or less.

  On the other hand, the Bi-2223 composition has a critical temperature (Tc) of 110 K and is practically usable even at the temperature of liquid nitrogen, but its superconductivity is sharply reduced when a weak magnetic field is applied. There is a problem.

  At the beginning, when Bi-2223 was discovered, it was very difficult to form a single phase, and Bi-2223 was a mixed phase with Bi-2212 or Bi-2201.

  However, by substituting a part of Bi with Pb, it is easy to make it a single phase. At present, a current lead of almost single-phase Bi-2223 has been obtained by a general solid-phase reaction method.

  The solid phase reaction method is a production method in which raw material powders are mixed, molded in a mold or rubber mold, and fired to react.

  On the other hand, Bi-2212 can be easily made into a single phase by melting it once and solidifying it slowly, and a mold covered with a sheath such as a wire does not require a mold at the time of manufacture. , Very effective. Further, since the magnetic field dependence at low temperature is smaller than that of Bi-2223, it is excellent when used under low temperature and strong magnetic field. However, in order to obtain a current lead, a casting method or a unidirectional solidification method is required to maintain the shape, and it is possible to produce by these methods, but fine control and time are required, and a general method is required. It is difficult to produce by a solid phase reaction method which is a technique.

  Therefore, at present, Bi-2223 compositions, which can be relatively easily manufactured, are widely used as current leads.

  As described above, the Bi-2223 composition widely used as a current lead is currently generally manufactured by a method of partially replacing Bi with Pb. Not at all.

  However, there are few reports that Bi-2223 is produced without partial substitution with Pb, and a substance close to a Bi-2223 single phase has been obtained. However, all of these reports are conducted on short samples, and are only evaluated by phase identification by X-ray diffraction, critical temperature measurement, and the like, and do not actually pass a current of several tens of amperes.

  The reason for this is that it is not possible to produce a large single-phase bulk of Bi-2223 without replacing part of Bi with Pb by a conventional manufacturing method.

  Therefore, it is difficult to obtain almost single-phase Bi-2223, and a large current of several hundred amperes has not been able to flow until now. In addition, the Bi-2223 composition almost single-phase produced without partial substitution by Pb has a disadvantage that the magnetic field dependency is larger than that of Bi-2223 partially substituted by Pb, which is disadvantageous. is there.

In addition, Bi-2223 and Bi-2212 may be in a mixed phase due to a difference in heat treatment conditions because of a composition in which Bi is partially replaced by conventional Pb. Since an impurity phase such as Ca ₂ PbO ₄ precipitates, the Bi-2223 phase is disturbed, and there is a problem that the superconductivity is greatly reduced.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems. For example, an oxide superconductor capable of obtaining a high-temperature superconductor at a practical level, for example, at a temperature of 77 K and a critical current density of 300 A / cm ² , and its production. It is an object to provide a method.

  Another object of the present invention is to provide a current lead using an oxide superconductor that has a small magnetic field dependence and exhibits superconductivity as a high-temperature phase due to a mixed phase state of Bi-2223 and Bi-2212. I do.

  The present invention relates to a current lead using a Bi-based oxide superconductor containing Sr, Ca, and Cu and not containing Pb, wherein the ratio between the Bi-2212 composition and the Bi-2223 composition is 1- X: X (X = 0.4 to 0.8).

  This will be described in more detail with reference to FIG.

FIG. 1 is a flow chart of the manufacturing process of the present invention, in which Bi ₂ O ₃ , SrCO ₃ , CaCO ₃ , and CuO are prepared as starting materials (step S1).

As these composition ratios,
Bi: Sr: Ca: Cu: O = 2: 2-X: 2-Y: 3-Z: δ
(X = 0.1 to 0.3, Y = −0.2 to 0.2, Z = −0.2 to 0.3, δ is arbitrary).

  Then, in step S2, the starting materials are mixed. Next, calcination is performed in step S3 and pulverization is performed in step S4 to obtain a superconducting material powder (step S5). Here, the calcination in step S3 and the pulverization in step S4 are repeatedly performed.

  As the calcination conditions, the temperature is maintained at 800 to 820 ° C. for 5 to 15 hours, the temperature raising and lowering rates are 1 to 3 ° C./min, and the atmospheric oxygen partial pressure is 5 to 15%.

  Outside the range of the oxygen partial pressure, the optimum temperature range becomes narrow, and it is necessary to control the temperature accurately (for example, with an accuracy of 1 to 2 ° C.). Therefore, Bi-2223 may not be generated due to a slight temperature shift. That is, it is necessary to perform the heat treatment within the range of the oxygen partial pressure.

  In step S6, it is formed into an arbitrary shape. For example, the current lead is a cylindrical body having a predetermined size.

  The heat treatment (NO. 1) in step S7 and the intermediate C.I. in step S8. I. P. (Cold isostatic pressing) is repeated a plurality of times (for example, two to three times).

  However, the first firing temperature is slightly higher than 850 to 870 ° C., and the second and subsequent firing temperatures are slightly lower than the first firing temperature of 840 to 860 ° C. The holding time of the sintering temperature was 100 hours, the temperature raising and lowering rates were 1 to 3 ° C./min, the atmospheric oxygen partial pressure was 5 to 15% in the first firing step, and the atmospheric oxygen partial pressure in the second and subsequent times. The pressure is equivalent to the atmosphere (about 22%).

Intermediate C. I. P. C. I. P. The pressure is 3000-4000 kgf / cm ² .

  In the last step S9, another heat treatment (NO. 2) is performed. Various conditions for this heat treatment are the same as those in the second and subsequent firing steps. Through such processing, a superconductor according to the present invention is obtained (step S10).

In the oxide superconductor and the method of manufacturing the same according to the present invention, when the superconductor is manufactured under the above-described firing conditions, the ratio between the Bi-2212 composition and the Bi-2223 composition becomes
1-X: X (X = 0.4 to 0.8).

  Although the superconductor obtained by the present invention has a lower critical current Ic at 77K than the conventional Bi-2223 obtained by partially replacing Bi with Pb, the superconductor has a critical current Ic and a critical current density Jc at a lower temperature. In addition to being able to be large, the dependence on the magnetic field is small, and deterioration at a low temperature and under a magnetic field can be suppressed.

  Moreover, a current lead or the like as an applied product can be manufactured by a conventional simple solid-phase reaction method (powder solid-phase method).

  The superconductor manufactured by the method for manufacturing an oxide superconductor according to the present invention can be applied to all Bi-based superconductors regardless of the current lead, for example, a silver sheathed wire, a cable, a magnetic shield, or Examples include a thin film. In particular, it is better for use under a magnetic field than the conventional one.

  As described above, according to the present invention, the firing temperature in the plurality of firing steps is set to be lower for the second and subsequent firing steps, so that a Bi-2212 composition and a Bi-2223 composition in a mixed phase are obtained. It is possible to provide a current lead using an oxide superconductor having both advantages of both compositions, a relatively high temperature phase, and excellent magnetic field characteristics.

Next, examples of the present invention will be described. First, according to the flow chart of FIG. 1, the raw material having the composition of Bi: Sr: Ca: Cu: O = 2: 1.7: 2.2: 3.2: δ (δ is arbitrary) has the firing temperature, the first 860 ° C. for the second time, 850 ° C. for the second time, heating and cooling rate of 2.5 ° C./min, first atmosphere oxygen partial pressure of 8% O ₂ , second atmosphere oxygen partial pressure of 22% O ₂ , And intermediate C.I. I. P. The characteristics of the current lead manufactured at a pressure of 3200 kgf / cm ² are shown in FIGS.

FIG. 2 is a graph showing the result of X-ray diffraction of the manufactured sample. This sample had a critical current Ic of about 300 A (however, a temperature of 77 K and a magnetic field of 0 T). The shape of the sample was a cylinder having a diameter of 20 × 100 Lmm and a thickness of 1.40 mm, and the critical current density Jc was about 320 A / cm ² .

  The upper graph in the figure is the current lead of the oxide superconductor according to the present invention, and the lower graph is the current lead of the conventional Bi-2223. A mark indicates the Bi-2212 composition, and a mark indicates the Bi-2223 composition.

  The sample according to the present invention has a mixed phase state of Bi-2212: Bi-2223 = 3: 7, and most of the conventional samples consist of peaks of the Bi-2223 composition, and the Bi-2223 composition is almost single phase. Understand.

  The oxide superconductor manufactured according to the present invention is a mixed phase of the Bi-2212 composition and the Bi-2223 composition, and has the advantages of both compositions.

That is, the oxide superconductor of the present invention can be used practically with a critical current density Jc of about 320 A / cm ² when the applied magnetic field is zero at a temperature around 77 K, and the temperature can be as low as 60 K or less. For example, even when a considerable applied magnetic field (for example, about 1 T) is applied, the critical current density Jc becomes 270 A / cm ² or more, which is practical.

That is, for example, at a temperature of 60 K and a magnetic field of 1 T, a condition where the critical current Ic is 300 A and the critical current density Jc is 320 A / cm ² or more can be satisfied.

  FIG. 3 is a graph of the critical current Ic at each temperature in the applied magnetic field 1T, in which a solid line indicates a current lead of the oxide superconductor according to the present invention, and a dotted line indicates a current lead of the conventional Bi-2223.

  As shown, under the applied magnetic field 1T, the critical current Ic of the current lead according to the present invention is 250A or more at a temperature of 60K, 900A or more at a temperature of 50K, and 1300A or more at a temperature of 40K. It can be used as a lead.

  Compared to the critical current Ic of the conventional current lead, the value is almost the same at the temperature of 50K, and the value of the current lead of the present invention is higher at the temperature of 40K.

FIG. 4 is a graph showing a critical current Ic / Ic _77K in a magnetic field standardized (normalized) at a critical current Ic _77K at a temperature of 77 K and a magnetic field of 0 T at each temperature. Conventional Bi-2223) are shown together.

  The critical current at a temperature of 77 K and a magnetic field of 0 T is 300 A in the case of the present invention and 1100 A in the conventional case.

At a temperature of 40K and a magnetic field of 1T, the current lead according to the present invention has a value of Ic / _Ic77K of about 4.5, conventionally about 1.0.

  At this time, the absolute value of the critical current Ic is 1350 A in the case of the present invention and 1100 A in the conventional case, and under this condition, the critical current of the current lead according to the present invention is larger than that of the conventional one. Become.

  For example, a current lead formed by a mixed phase of Bi-2223 and Bi-2212 is applied to the magnetic field generator shown in FIG.

The magnetic field generator 50 mainly includes a superconducting magnet 51 of Nb ₃ Sn, a first stage 52, a second stage 53, and a refrigerator 54. The superconducting magnet 51 is attached to the second stage 53, and is cooled to 7K by the refrigerator 54. The superconducting magnet 51 generates a magnetic field of 2.5 T at a current of 100 A and has a bore diameter of 50 mm at room temperature.

Further, a first current lead 55 formed by a mixed phase of Bi-2223 and Bi-2212 is connected between the first stage 52 and the second stage 53. In this case, the first current lead 55 is formed into a cylindrical tube having a diameter of 20 mm and a length of 150 mm. Further, the first current lead 55 has a critical current of 300 A at 77 K and a critical current density of 300 A / cm ² .

  The second current lead 56 made of copper is connected between the first stage 52 and the refrigerator 54. In this case, the first stage 52 has a temperature around 45K. As described above, the first current lead 55 is connected to the first stage 52 at the high temperature end (45K), and is connected to the second stage 53 at the low temperature end (7K).

  Under such a configuration, current is supplied to the first stage 52 via the second current lead 56, and further supplied from the first stage 52 to the superconducting magnet 51 via the first current lead 55. In this case, when the superconducting magnet 51 generates a magnetic field of 2.5T, the high-temperature end A of the first current lead 55 is exposed to a magnetic field of 0.07T, and the low-temperature end B of the first current lead 55 is set to 0.1. It is exposed to a 2T magnetic field.

  Next, FIG. 6 shows the performance (characteristics) of the first current lead 55 when the first current lead 55 is applied to the magnetic field generator 50 shown in FIG. FIG. 6 shows the temperature of the high-temperature end A, the temperature of the low-temperature end B, and the voltage of the high-temperature end A. Here, the voltage at the high temperature end A indicates the contact resistance of the first current lead 55.

  When the current is zero, the temperatures at both ends A and B of the first current lead 55 are 10K and 45K, respectively. When the current increases to 100 A, a magnetic field of 2.5 T is generated at the center of the bore of the superconducting magnet 51. As a result, the first current lead 55 is exposed to a magnetic field of 0.2T at the low temperature end B and 0.07T at the high temperature end A. When a current of 100 A is supplied, a voltage of 0.25 mV is applied to the hot end A of the first current lead 55. This voltage is caused by the contact resistance.

  As shown in FIG. 6, when a current is supplied to the superconducting magnet 51, the temperatures of the high-temperature end A and the low-temperature end B increase. However, when the current is held, the temperature is kept constant.

  In fact, current was supplied to the superconducting magnet 51 via the first current lead 55 for two hours. As a result, it was confirmed that the temperature and the voltage of the first current lead 55 were kept almost constant and the magnetic field was generated stably. Thus, the mixed-phase first current lead 55 is at a sufficiently practical level as the current lead of the magnetic field generator 50 shown in FIG.

It is a flowchart figure of the manufacturing process of this invention. It is a graph which shows the X-ray diffraction result of the same manufactured sample. It is a graph of the critical current Ic at each temperature in the same applied magnetic field 1T. Same, at each temperature, a graph showing the temperature 77K, a critical current Ic / Ic _77K in a magnetic field normalized by the critical current Ic _77K in a magnetic field 0T. 1 is a schematic diagram of a magnetic field generator to which a current lead of the present invention is applied. 6 is a graph showing the performance (characteristics) of the current lead shown in FIG.

Explanation of reference numerals

Reference Signs List 50 magnetic field generator 51 superconducting magnet 52 first stage 53 second stage 54 refrigerator 55 first current lead 56 second current lead

Claims (1)

A current lead using a Bi-based oxide superconductor containing Sr, Ca, and Cu and not containing Pb,
A current lead using an oxide superconductor, wherein a ratio between a Bi-2212 composition and a Bi-2223 composition is 1-X: X (X = 0.4 to 0.8).

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