Patent Description:
MgB<NUM>, as a metal-based superconductor, which has the highest critical temperature of about <NUM>, is expected to be applied as a superconducting wire or a superconducting magnet.

A general preparation method of a superconducting wire is a powder-in-tube (PIT method). In this method, a metal tube is filled with base powder, a diameter reduction is performed by a method of drawing, and thereby it is possible to prepare a single-core wire (wire having one superconducting filament). In addition, when a metal tube is filled with single-core wires and is subjected to the diameter reduction again, a multi-core wire (wire having a plurality of superconducting filaments) is obtained. A method of using MgB<NUM> as the base powder is referred to as an ex situ method. A method of using a mixture of magnesium powder and boron as the base powder is referred to as an in situ method.

When a superconducting wire is used, it is desirable that the superconducting wire has a high critical current density. The critical current density means upper limit current density at which it is possible to perform energization with zero resistance. The critical current density of a superconductor is determined by flux pinning. Lines of magnetic flux are quantized and infiltrate into a (type-II) superconductor, and the Lorentz force acts on the lines of magnetic flux during energization. When the lines of magnetic flux make movement due to the Lorentz force, a loss occurs. Therefore, in order to obtain the high critical current density of the superconductor, it is necessary to introduce defects or inhomogeneities to the superconductor such that the lines of magnetic flux has pinning.

In MgB<NUM>, the flux pinning is likely to mainly occur on a crystal grain boundary. In order to increase the flux pinning of the crystal grain boundary, it is effective to reduce crystallinity and to decrease a grain size. MgB<NUM> has high crystallinity at a temperature range of <NUM> or above and is likely to achieve grain growth. However, in terms of flux pinning, synthesis at a low temperature of <NUM> or below is effective to achieve high critical current density of MgB<NUM> (for example, see NPL.

As described above, the characteristics and problems of the most general in situ method and ex situ method in the PIT method are described; however, various attempts to obtain high critical current density, in addition to the methods described above, have been made. As an example, high-energy mixing of magnesium powder and boron powder is performed by using a planetary ball mill apparatus, and thereby an attempt to increase the reactivity of the powders has been made. Hereinafter, this method will be referred to as a mechanical milling method. In the mechanical milling method, there have been reports that a part of MgB<NUM> is produced by mixing energy even when the heat treatment is not performed, MgB<NUM> synthesized in this manner has a high reactivity, and the high critical current density is obtained (for example, see NPLs <NUM>, <NUM>, <NUM>, and <NUM> and PTL <NUM>).

Further products of the prior art are described in <CIT>, <CIT>, <CIT>, <CIT> and <CIT>.

As described above, the reports that the high critical current density is obtained in the mechanical milling method have been made; however, a shape of tape-shaped wire is used in most of the reports. Although there have been some reports of using a round wire, the critical current density is not at all high. In addition, there has been a report that, with a tape wire obtained by the mechanical milling method, a value of the critical current density significantly changes depending on an angle formed between a tape surface and an external magnetic field (for example, see NPL <NUM>).

In an application to a magnetic resonance imaging (MRI) apparatus in which high magnetic field homogeneity is demanded, it is preferable to use a shape of which a round or angular cross section is highly symmetrical. A tape wire having a high aspect ratio is difficult to secure dimensional accuracy of winding wire. Additionally, it is not highly preferable that a wire having critical current density that is anisotropic to a magnetic field direction impose restriction to coil design. Here, an aspect ratio (width/thickness) of a typical MgB<NUM> tape wire is about <NUM>. In addition, anisotropy of the critical current density of the MgB<NUM> tape wire depends on a temperature and a magnetic field; however, some MgB<NUM> tape wires have the anisotropy of about <NUM> to <NUM>.

According to the present invention, an object thereof is to provide a wire which has a round or angular shape with good symmetry, in which anisotropy of critical current density is not generated, and which exhibits potential of high critical current density obtained by a mechanical milling.

A superconducting wire according to the present invention includes: a MgB<NUM> filament as defined by claim <NUM>. According to another aspect, the invention also provides a precursor as defined by claim <NUM>.

The MgB<NUM> wire of the present invention has a round or angular cross-sectional shape which is used without imposing restriction to design of a superconducting device and exhibits potential of the high critical current density by the mechanical milling method.

Hereinafter, embodiments of the present invention will be described with reference to the figures.

In order to achieve the object described above, the present invention prepares MgB<NUM> wire by the following procedure. High-energy mixing of magnesium powder and boron powder is performed by using a planetary ball mill apparatus. At this time, it is preferable that mixing energy is set to the extent that the boron powder is dispersed in the magnesium powder, and production of MgB<NUM> is not caused (to the extent that a production peak of MgB<NUM> is not generated in at least powder X-ray diffraction). A metal tube is filled with mixed powder and is reduced in diameter. At this time, at least some of processing steps, like cassette rolling or groove rolling, employ a processing method, in which a portion of a processing jig which comes into direct contact with the wire is not fixed but rotates. Otherwise, in a case of using a technique like drawing in which a portion of a jig that comes into direct contact with the wire is immovable, a processing material is processed while being heated at a degree of temperature at which MgB<NUM> does not substantially produced.

A precursor prepared in such a method (a state before heat treatment is performed before MgB<NUM> is produced) has the following characteristics. Particles of boron are dispersed in a matrix of magnesium in a portion of the precursor of a MgB<NUM> filament in a longitudinal section of the precursor of the MgB<NUM> wire, and number density of voids each having a major axis of <NUM> or larger is in a range of <NUM> to <NUM>-<NUM>. The void is likely to be oriented to a direction perpendicular to an axial direction of the wire.

In addition, the MgB<NUM> wire has a round or angular cross-sectional shape which is used without imposing restriction to design of the superconducting device and exhibits potential of the high critical current density by the mechanical milling method. An aspect ratio of the MgB<NUM> wire of the embodiment is <NUM> or lower. An aspect ratio (width/thickness) of a typical MgB<NUM> tape wire is about <NUM>.

In addition, anisotropy of the critical current density is <NUM> or lower at every temperature magnetic field region. Here, when θ represents an angle formed between an axis of the MgB<NUM> wire and an external magnetic field, and Jc(θ) represents dependence of Jc on θ, the anisotropy of the critical current density is defined as a ratio of the maximum value and the minimum value of Jc(θ).

In addition, the MgB<NUM> wire prepared in this method has the following characteristics. The number density of voids each having the major axis of <NUM> or larger in the portion of the MgB<NUM> filament is, specifically, in a range of <NUM> to <NUM>-<NUM> in the longitudinal section of the MgB<NUM> wire. The void is likely to be oriented to a direction perpendicular to the axial direction of the wire.

In a case of preparing a multi-core wire, after single-core wires are prepared, a plurality of the single-core wires are embedded in a metal tube, and a diameter reduction is performed. At some of processing steps after the wires are put in, like cassette rolling or groove rolling, employ a processing method, in which a portion of a processing jig which comes into direct contact with the wire is not fixed but rotates. Otherwise, in a case of using a technique like drawing in which a portion of a jig that comes into direct contact with the wire is immovable, a processing material is processed while being heated at a degree of temperature at which MgB<NUM> does not substantially produced. At this time, a sectional configuration, in which iron is disposed around a MgB<NUM> filament, and a material having hardness higher than pure copper is disposed on the outermost circumference, may be employed.

Magnesium powder having a grain size of smaller than <NUM> mesh and purity of <NUM>% and boron powder having a grain size of smaller than <NUM> and purity of <NUM>% were used as base powders.

The magnesium powder and the boron powder are weighed to have Stoichiometric composition (a mole ratio of <NUM>:<NUM>), and two types of mixed powders I and M are prepared. The mixed powder I is obtained by containing base powder together with a stainless steel ball having a diameter of <NUM> in a plastic container and mixing by a ball mill device. The mixed powder M is obtained by containing <NUM> of base powder together with <NUM> zirconia balls each having a diameter of <NUM> in a zirconia container having a volume of <NUM> and mixing in conditions of <NUM> rpm for six hours by a planetary ball mill device.

<FIG> is a schematic diagram of dies which are used in drawing. An iron tube having an outer diameter of <NUM> and an inner diameter of <NUM> was filled with each of the mixed powders, the iron tube was reduced to have a diameter of <NUM> by drawing, and a wire (precursor of the MgB<NUM> wire) was prepared. Here, the drawing is a processing method in which the wire is caused to pass through a hole <NUM> of an empty tapered dies <NUM> as shown in <FIG>. The wire is caused to repeatedly pass through the hole <NUM> of the dies while the dies are replaced with dies having a smaller hole <NUM> gradually, and thereby it is possible to reduce the diameter of the wire.

Heat treatment was performed in conditions of a temperature of <NUM> for three hours in an argon atmosphere, in order to produce MgB<NUM>. The wires prepared from both of mixed powders I and M are called Wire-I and Wire-M, respectively.

The mixed powder M was prepared in the same method as that in Comparative Example <NUM>. An iron tube having an outer diameter of <NUM> and an inner diameter of <NUM> was filled with the mixed powder M, the iron tube was reduced to have a diameter of <NUM> by drawing. Subsequently, the iron tube was reduced to have a diameter of <NUM> by cassette rolling.

<FIG> is a schematic diagram of dies which are used in the cassette rolling. As shown in <FIG>, in the dies <NUM> of a cassette roll, rolls <NUM> are attached to a roll fixing instrument <NUM>, and grooves <NUM> are cut in the rollers. The wire is caused to repeatedly pass through the grooves <NUM> while the dies are replaced with dies having smaller grooves <NUM> gradually, and thereby it is possible to reduce the diameter of the wire. The wire receives a force from the fixed dies in the drawing, and the wire receives a force from rotating rolls in the cassette rolling.

Heat treatment was performed in conditions of a temperature of <NUM> for three hours in an argon atmosphere, in order to produce MgB<NUM>. The prepared wire is called Wire-MR.

The critical current density of the three MgB<NUM> wires prepared in Comparative Example <NUM> and Example <NUM> was evaluated. While the temperature of the wires was controlled by spraying of helium gas and heating by a heater, an external magnetic field was applied in a perpendicular direction to an axis of the wire, and current-voltage characteristics were achieved by a DC four-terminal method. A critical current is defined as a current value obtained when a voltage of <NUM>µV/cm is generated, and the critical current density is defined as a value obtained by dividing the critical current by a cross-sectional area of a MgB<NUM> filament on a cross section of the wire.

<FIG> shows magnetic field dependence of the critical current density of a prepared single-core wire at <NUM>. Wire-MR had the highest critical current density and, subsequently, the critical current density was high in an order of Wire-I and Wire-M. The result of the above description showed that, by performing a combination of the drawing and the cassette rolling on the mixed powder obtained by the mechanical milling, the high critical current density was obtained.

Microstructure of the three MgB<NUM> wires prepared in Comparative Example <NUM> and Example <NUM> was observed. The wire was dried and polished after resin filling, and then a smooth wire-longitudinal-section sample was prepared by cross-section polisher processing (CP processing). The sample was observed with a scanning electron microscope.

<FIG> shows schematic diagrams of longitudinal sections of prepared wires (after the heat treatment) in Comparative Example <NUM> and Example <NUM>. <FIG> shows photographs of the longitudinal sections of the prepared wires (after the heat treatment) in Comparative Example <NUM> and Example <NUM>. Both of the wires were configured to have a filament <NUM> in which MgB<NUM> is a main phase and an outer-layer metal member <NUM> in common, and presence of voids <NUM> were recognized in the MgB<NUM> filament. On the other hand, the number and directions of voids were remarkably different depending on the wires. In Wire-I, many voids were recognized, and most of the voids were observed to extend in an axial direction of the wire. On the other hand, in Wire-M and Wire-MR, many voids were observed to extend in a direction orthogonal to the axis of the wire. In addition, the number of voids in Wire-M is greater than the number of voids in Wire-MR. For example, the outer-layer metal member <NUM> is made of iron.

<FIG> is a schematic diagram for describing definition of a major axis of a void. A shape of the void <NUM> in each of the wires was quantified by the following method. The major axis of the void <NUM> is defined as follows: a line having the longest length of lines connecting two points on an outer circumference of the void on the longitudinal section is defined as the major axis of the void. For example, as in <FIG>, in a case where the void <NUM> is present in the filament <NUM> in which the main phase is MgB<NUM>, a white dashed line is the major axis.

Hereinafter, only voids each having the major axis of <NUM> or larger are targets, and number density n of the voids and an average value θM of angles θ (<NUM>° ≤ θ ≤ <NUM>°) formed between the axis of the wire and the major axis of each of the voids are considered. Here, the voids each having the major axis of <NUM> or larger within a visual field by SEM observation are numbered (i = <NUM>, <NUM>, <NUM>, ···, and N). When an angle formed between a major axis of an i-th void and the axis of the wire is θi, θM is defined by Expression (<NUM>).

Results of obtaining n and θM of the three wires are shown in Table <NUM>. The values are results of obtaining lengths of the major axes of the voids MgB<NUM> and angles between the axis of the wire and the major axis of each of the voids and averaging the lengths and angles in a plurality of square regions having a length of <NUM> per side of the MgB<NUM> filament. Wire-I and Wire-M had a high number density of the voids, and Wire-MR had a low number density of the voids. Hence, the high critical current density of Wire-MR is considered to be obtained due to the dense MgB<NUM> filament and an increase in the ratio of a sectional area which can be an effective current path. Wire-I and Wire-M have the same degree of the number density of voids; however, Wire-I has the higher critical current density. This difference is due to a difference of θM. In other words, since Wire-M has large θM, and thus the voids are oriented to a direction orthogonal to the axis of the wire, in which the voids are more likely to block the current path, a ratio of the sectional area which becomes the effective current path is decreased, and thus the critical current density is considered to be decreased.

Microstructure on longitudinal sections of the three wires before the heat treatment (that is, precursors of the MgB<NUM> wires) prepared in Comparative Example <NUM> and Example <NUM> was observed. <FIG> shows schematic diagrams of the longitudinal sections of the prepared wires (before the heat treatment) in Comparative Example <NUM> and Example <NUM>. <FIG> shows photographs of the longitudinal sections of the prepared wires (before the heat treatment) in Comparative Example <NUM> and Example <NUM>. Both of the wires were configured to have the filament <NUM> in which magnesium and boron are main phases and the outer-layer metal member <NUM>. In Wire-I, a region <NUM> filled with boron particles is present in a gap between magnesium particles <NUM> elongated in the axial direction of the wire. A size and a distribution of magnesium particles <NUM> are substantially equal to those of the voids <NUM> after the heat treatment. This is because magnesium is diffused into the regions <NUM> filled with the boron particles and MgB<NUM> is produced in Wire-I, and the portions, in which magnesium particles are originally present, become the voids <NUM>. The filament <NUM> of Wire-M was configured to have a uniform structure <NUM> and the voids <NUM> in which regions filled with magnesium particles and boron were not distinguished. It was found that there was no significant change in distribution of the voids <NUM> before and after the heat treatment, and the voids <NUM> in Wire-M after the heat treatment remained as the voids <NUM> formed during the processing of the wire. Similar to Wire-M, the filament of Wire-MR was configured to have the uniform structure <NUM> and the voids <NUM> in which regions filled with magnesium particles and boron were not distinguished. There was no significant change in the distribution of the voids before and after the heat treatment. Hence, the number density of the voids in Wire-MR is decreased after the heat treatment, because the number density of the voids formed during the processing of the wire is small.

<FIG> shows schematic diagrams of Wire-I, Wire-M, and Wire-MR. On the left, an enlarged schematic diagram of the region <NUM> filled with boron particles in (a) Wire-I is shown. On the right, an enlarged schematic diagram of the uniform structure <NUM> in (b) Wire-M and Wire-MR is shown. In Wire-M, filling of boron particles <NUM> having a grain size of about <NUM> is performed, and gaps between boron particles <NUM> were present. Since the boron particles are hard and do not deform, gaps always remain in the regions filled with boron particles. On the other hand, when a portion viewed to have the uniform structure <NUM> in Wire-M and Wire-MR was enlarged, it was found that a structure, in which the gaps between boron particles <NUM> were filled with magnesium <NUM>, is formed. <FIG> shows photographs of Wire-I, Wire-M, and Wire-MR.

An observation result of the microstructure suggests that following phenomenon occurs in a process of preparing the wire. A mixing method of base powders influences the distribution of magnesium and boron. In the ball mill mixing of Wire-I, the base particles are mixed as the particles maintain their original shapes. In the drawing, the magnesium particles are subjected to plastic deformation and are elongated in the axial direction of the wire. On the other hand, since the boron particles are hard, the filling rate thereof is increased while the boron particles are repeatedly redisposed without being deformed; however, gaps between boron particles remain until the end. When the heat treatment for synthesizing MgB<NUM> is performed, magnesium is diffused into the regions filled with the boron particles, and MgB<NUM> is produced. However, such a reaction is a volume contraction reaction, and thus the regions, where magnesium is present, remains as voids. When high-energy mixing is performed by using planetary ball milling like Wire-M, the boron particles are kneaded with the magnesium particles in the process of mixing, and powder having a structure in which magnesium as a matrix contains boron is obtained. Powder filled portions are elongated by the drawing; however, plastic deformability of the magnesium particles containing the boron is degraded. Therefore, many voids oriented to the direction perpendicular to the axial direction of the wire are formed without sufficient elongation in the process of the drawing, and thus a filament having bad continuousness is obtained. The voids remain even after the heat treatment and results in a decrease in critical current density. The number density of the voids is very low in Wire-MR, and this suggests that the cassette rolling is effective to block the voids.

The conditions of a planetary ball mill process for preparing the mixed powder are described in detail above; however, what is important is that powder having a structure, in which magnesium as the matrix contains boron, is used. When the powder having the structure is obtained, regardless of conditions of the planetary ball mill process, a method other than the planetary ball mill process may be used. In the planetary ball mill process, the smaller the number of rotations, the smaller the revolution radius, the lower the ratio of total weight of balls to total weight of powder, the larger the inner diameter of the ball, and the shorter the processing time, the more the magnesium and the boron are mixed as maintaining the original shapes. On the other hand, in the planetary ball mill process, when the number of rotations is too large, the revolution radius is too large, the ratio of total weight of balls to total weight of powder is too high, the inner diameter of the ball is too small, and the processing time is too long, the magnesium and the boron react with each other, and MgB<NUM> is produced. Hence, such parameters need to be set within an appropriate range in the planetary ball mill process. NPL <NUM> discloses a relationship between the conditions of the planetary ball mill process and the mixing energy and discloses that the mixing is performed with energy of <NUM> J/kg per unit weight of powder, thereby producing a phase of MgB<NUM> during the mixing, and such powder is used, thereby increasing the critical current density of the MgB<NUM> wire. However, the present invention significantly differs from NPL <NUM> in that the mixing energy in the present invention is lower than <NUM> J/kg, and thus the mixing is performed in a range in which the production of MgB<NUM> does not occur. In addition, it is checked that production of MgB<NUM> does not actually occur in the powder after the substantial mixing.

Here, the process is referred to as the cassette rolling; however, the process may be referred to as various ways such as a roll forming process, roll forming, cold roll forming, and cold rolling. All of the processes are performed by causing a target object to pass between a plurality of rotating processing jigs and performing deformation processing (diameter reduction). Compared to the drawing in which the wire receives the force from the fixed dies, the cassette rolling is considered to be effective in that a small frictional force is generated between the target object and the dies, damage to filling powder is small because the target object is elongated while the center of the target object is compressed, and the powder is better compressed to be densified.

The high critical current density is realized by adding the cassette rolling to the wire subjected to the mechanical milling method; however, the characteristics of the microstructure are that the number of coarse void is small (n is small) and the coarse voids are oriented to a direction perpendicular to a longitudinal direction of the wire (θM is large).

In Example <NUM>, the outer diameter was reduced from <NUM> to <NUM> in the drawing, and the outer diameter was reduced from <NUM> to <NUM> in the cassette rolling. In other words, the processing method was switched during the reduction at the diameter of <NUM>, and thereby it was checked that n is small. In the example, the outer diameter, where the processing method was switched, was changed. As a result, when the outer diameter, where the processing method was switched, was larger, it was observed that n tend to be smaller. However, even in a case where the entire process is configured of the cassette rolling, a value of n is <NUM>-<NUM>. In addition, in a condition in which n exceeds <NUM>-<NUM>, the critical current density is not substantially changed from that of Wire-I, and thus employment of the mechanical milling method is not highly superior. In addition, regarding the value of θM, no systematic change is observed with respect to the outer diameter where the processing method is switched, and an evaluated sample at this time satisfies θM ≥ <NUM>°.

Conditions of the number density and shapes of voids are described. Wire-I, Wire-M, and Wire-MR were representative examples; however, as a result of preparing the wires a plurality of times, it was found that the wires prepared under the same conditions has unique characteristics. In both of a case where the powder is mixed by the ball mill device and a case where the powder is mixed by the planetary ball mill device (mechanical milling), the number density of voids is within a numerical value of about <NUM> × <NUM>-<NUM> or higher. In the case where the powder is mixed by the planetary ball mill device, the number density of voids varies within a range of <NUM> to <NUM>-<NUM> through a step of reducing the diameter of the metal tube by further causing the metal tube filled with the mixed powder to pass between the plurality of rotating processing jigs.

In the case where the powder is mixed by the ball mill device, an average value of angles (defined from <NUM> to <NUM> degrees) formed between the major axis of each of the voids and the axis of the wire (or the precursor) is smaller than <NUM> degrees. In the case where the powder is mixed by the planetary ball mill device (mechanical milling), the average value of the angles is <NUM> degrees or larger.

As described above, a difference in directions of the voids is due to a difference in mechanism of forming the voids. In the case where the powder is mixed by the ball mill device, the energy that is applied to the powder is low, and thus the mixing is performed as magnesium and boron maintain their original shapes. When the metal tube is filled with the mixed powder and is subjected to the drawing, the soft magnesium is stretched and elongated in the longitudinal direction of the wire. Since the magnesium is diffused into the regions of the boron powder by the heat treatment, and MgB<NUM> is produced, the regions in which the magnesium is originally present is changed to voids. The voids reflect the original shape of the magnesium and has a shape extending in the longitudinal direction of the wire, and an angle formed between the major axis of the void and the wire is small. On the other hand, in the case where the powder is mixed by the planetary ball mill device, the energy that is applied to the powder is high, and thus boron particles are kneaded in magnesium. Particles obtained by dispersing boron into a parent phase of magnesium is harder than pure magnesium particles and are difficult to perform plastic deformation. When the process is performed by filling the metal tube with the mixed powder, gaps are likely to be formed between powders adjacent in the longitudinal direction of the wire. In particular, since a force of a tensile component in the longitudinal direction of the wire is strong in the drawing, the voids between the powders are remarkably formed. Since the process proceeds such that the powder is stretched in the longitudinal direction while being crushed in a radial direction of the wire in the cassette rolling, slight deformation occurs even in hard powder, gaps between powder is filled, and thus the number density of voids is small.

It has been known that a crystalline boron site is substituted with carbon atoms in MgB<NUM>, thereby shortening a mean free path of electrons, and the critical current density of a high-magnetic field range is improved by improving an upper critical field. In the example, boron carbide powder having a grain size of <NUM> was added. The powder was weighed so as to obtain composition of Mg + <NUM>. 80B + <NUM>. 04B<NUM>C, and a wire was prepared in the same method of preparing Wire-MR.

<FIG> shows the magnetic field dependence of the critical current density of the prepared single-core wire at <NUM>. As shown in <FIG>, by adding B4C, further improvement in the critical current density was verified. Hence, it was possible to verify the effect of substitution with carbon in a method using both of the mechanical milling method and the cassette rolling.

In Example <NUM>, fine boron carbide powder was added. Here, the added substance is not limited to the boron carbide, the same effect is obtained even when carbon powder or metallic carbide powder is added. In general, substitution efficiency of carbon depends on a grain size or a type of added material; however, since the powder is mixed by applying high energy by the planetary ball mill device in the mechanical milling method, the substitution efficiency tends to be high even with a material of which substitution efficiency is degraded in a common mixing method and is not suitable for the added material.

In the comparative example, the mechanical milling method is applied to manufacturing of a multi-core wire.

A copper-iron composite tube having an outer diameter of <NUM> and an inner diameter of <NUM> was prepared. The copper-iron composite tube is formed of copper on an outer side and iron on an inner side thereof. After the composite tube is filled with mixed powder M, the composite tube is subjected to the drawing to obtain the outer diameter of <NUM>. Next, a wire was processed to have a hexagonal cross section having an opposite side length of <NUM> through hexagonal dies, and a hexagonal wire was prepared. Eight hexagonal wires were disposed around a hexagonal copper rod having a cross-sectional shape, in which an opposite side length was <NUM>. After an outerside of the eight hexagonal wires was covered with a copper tube having an outer diameter of <NUM> and an inner diameter of <NUM>, a copper wire was inserted into a gap, and an embedded member was prepared. This embedded member was reduced to have an outer diameter of <NUM> in the drawing and to have an outer diameter of <NUM> in the cassette rolling, and a multi-core wire was prepared. Heat treatment was performed on the multi-core wire in conditions of a temperature of <NUM> for three hours in an argon atmosphere, in order to produce MgB<NUM>.

<FIG> shows a cross section of the prepared multi-core wire in Comparative Example <NUM>. MgB<NUM> filaments <NUM> covered with a barrier layer <NUM> made of iron were disposed in a circle in a stabilizing layer <NUM> made of copper. As a result of observing details of the sections of the wire, it was recognized that eight MgB<NUM> filaments have a defect in shape, and there were positions at which the iron layer that originally separates the copper from the MgB<NUM> filament is broken. As a result of determining the critical current at a temperature of <NUM>, the critical current was zero even in a magnetic field 0T. This is because the iron is broken, the mixed powder M and the copper are brought into contact with each other, and the magnesium contained in the mixed powder reacts with the copper, and thereby a lack of magnesium that is required to produce MgB<NUM> occurs.

In Comparative Example <NUM>, materials of an outer-layer member of the hexagonal wire, the hexagonal rod at the center, and the outer-layer member of the embedded member were changed, and a multi-core wire was prepared. The outer-layer member of the hexagonal wire and the hexagonal rod at the center are made of iron, and the outer-layer member of the embedded member is a Monel-copper composite tube. Here, the Monel-copper composite tube is formed of Monel on an outer side and copper on an inner side thereof.

<FIG> shows a cross section of a prepared multi-core wire in Example <NUM>. MgB<NUM> filaments <NUM> were disposed in a circle in a barrier layer <NUM> made of iron. The outermost layer <NUM> made of Monel are separated from the barrier layer <NUM> made of iron by the stabilizing layer <NUM> made of copper.

The eight MgB<NUM> filaments had substantially the same shape, no particular breaking was recognized even in the iron on the outer circumference of the MgB<NUM> filament, and it was found that good sectional shapes are obtained.

Deformability of the mixed powder prepared by the mechanical milling method is degraded because boron is contained in magnesium as described above. Therefore, the mixed powder pierces the barrier layer <NUM> in the process in some cases. Form a result of this time, when all of the MgB<NUM> filaments <NUM> have a configuration shown in <FIG> in which the MgB<NUM> filaments are connected via a barrier member, the configuration is effective to prevent the barrier layer <NUM> from being broken.

It is important that a material of the barrier layer <NUM> does not substantially react with the magnesium when the heat treatment for producing MgB<NUM> is performed. In a case of a configuration in which the material that reacts with the magnesium is brought into contact with the MgB<NUM> filament, a lack of magnesium for producing MgB<NUM> occurs. Examples of materials which do not substantially react with magnesium include niobium, tantalum, titanium, and the like, in addition to iron, and the materials may be used as the material for a main component of the barrier layer <NUM>.

In a case where a material of the outermost layer is soft like copper, the MgB<NUM> filament <NUM> is likely to have a defect in shape, and covering the stabilizing layer <NUM> with a high-strength material such as Monel as in the example is effective. Nickel, cupronickel, iron, or the like, in addition to Monel, may be used as a material of the outermost layer <NUM>. It is preferable that the material of the outermost layer <NUM> has Vickers hardness higher than copper.

In the example, the multi-core wire having eight filaments is described; however, it is possible to call a wire having at least two filaments as the superconducting multi-core wire. In addition, the wire may have more than eight filaments. In the superconducting wire, the filament has a small diameter, and thus it is preferable that a large number of filaments are used such that it is possible to avoid a problem of magnetic instability or an AC loss. As an example, <FIG> shows a cross section of a <NUM>-core wire.

In preparing the MgB<NUM> wire using the mixed powder by the mechanical milling method, it is important to add the cassette rolling instead of the drawing. This is because the cassette rolling is effective to improve the filling rate of the mixed powder by the mechanical milling method after the deformability of the mixed powder is degraded. As long as there is a technique in which it is possible to improve the filling rate of the mixed powder by the mechanical milling method, there is no need to be limited to the cassette rolling.

For example, magnesium is hexagonal metal, and thus a sliding surface is limited. Therefore, it is difficult to perform processing on magnesium; however, when magnesium is heated to a temperature of <NUM> or above, the processibility is improved. The mixed powder obtained by the mechanical milling method has the structure in which boron is dispersed into the matrix of magnesium. Therefore, when the deformability of the matrix is improved by warm processing, the processibility is improved. Hence, even without using the cassette rolling, it is possible to obtain good microstructure of MgB<NUM> by warm drawing.

However, when a temperature for the warm drawing is too high, brittle MgB<NUM> is produced by the reaction of magnesium and boron, and thus the processibility deteriorates. Therefore, it is preferable that the processing temperature is <NUM> at the highest.

In the example, two methods of preparing a superconducting coil using the superconducting wire of the embodiment are described.

A first method is a wind·and·react method, in which the superconducting wire is wound around a bobbin, and then the heat treatment is added as necessary. In a case of preparing the superconducting coil, it is not possible to increase an excitation speed of the coil when a short circuit occurs between the superconducting wires. Therefore, it is preferable that the superconducting wire is covered with an insulation material. In the wind·and·react method in which the heat treatment is performed in a post-process, a material such as glass material that withstands the heat treatment is used as the insulation material. Then, after the heat treatment is performed, the superconducting wire is fixed by performing resin impregnation as necessary.

A second method is a react·and·wind method, in which the superconducting wire is subjected to the heat treatment, and then the superconducting wire is wound around a bobbin. In this case, it is possible to cover the superconducting wire with the insulation material after the heat treatment, and it is possible to use enamel or the like that does not have heat resistance as the insulation material. After the superconducting wire is wound around the bobbin, the superconducting wire is fixed by performing resin impregnation as necessary.

In the example, a configuration of an MRI <NUM> using the superconducting wire of the embodiment is described. <FIG> is a view of a configuration of the MRI.

A superconducting coil <NUM> using the superconducting wire, along with a persistent current circuit switch <NUM>, is stored in a cryostat <NUM> and is cooled in a refrigerant or a refrigerator. Persistent current flowing in a circuit that makes the superconducting coil <NUM> and the persistent current circuit switch <NUM> generates a magnetostatic field having high time stability at a position of a measurement target. The higher the magnetostatic field intensity, the higher the nuclear magnetic resonance, and the frequency resolution is improved. A time-varying current is supplied to a gradient coil <NUM> from an amplifier <NUM> for a gradient magnetic field, and a magnetic field having a spatial distribution is generated at a position of a measurement target <NUM>. Further, an oscillating field having a nuclear magnetic resonance frequency is applied to the measurement target <NUM> by using a radio frequency (RF) antenna <NUM> and a RF transmitting/receiving device <NUM>, a resonance signal that is emitted from the measurement target is received, and it is possible to perform tomographic imaging of the measurement target.

In the example, a vertical magnetic field open MRI using the superconducting wire of the embodiment is described. <FIG> is a perspective view of a vertical magnetic field MRI <NUM>.

The MRI includes a pair of magnetostatic field generating units <NUM> and a connecting member <NUM>, the units and the member are connected such that a central axis Z directing a vertical magnetic field is a rotation target axis. A space formed by the pair of magnetostatic field generating units and the connecting member is referred to as an imaging region <NUM>. A gradient magnetic field generating portion is present in a state in which the imaging region is narrowed. In addition, the MRI includes a bed <NUM> on which the measurement target is placed and a transport mechanism <NUM> that transmits a measurement target <NUM> to the imaging region. Further, the MRI includes a RF oscillator <NUM> that irradiates the imaging region with an electromagnetic wave having resonance frequency which cause a nuclear magnetic resonance phenomenon to the measurement target, a receiving coil <NUM> that receives a nuclear magnetic resonance signal, a control device <NUM> that controls units of the MRI, and an analysis device <NUM> that analyzes the signal, as the other constituent units not shown in the perspective view.

The pair of magnetostatic field generating units each includes the superconducting coil and generates a uniform magnetostatic field in the imaging region by the superconducting coil. The gradient magnetic field generating portion superimposes gradient magnetic fields in three directions which are orthogonal to the imaging region by any case of switching, on the uniform magnetostatic field such that the magnetic field intensity is gradient in the imaging region. The superimposed gradient magnetic fields imparts positional information to the nuclear magnetic resonance signal, the nuclear magnetic resonance phenomenon appears in a region of interest (a slice plane having a thickness of <NUM> in usual) over the imaging region, and an tomographic image of the measurement target is achieved.

Here, an example of the vertical magnetic field open MRI is described; however, the embodiment can be also applied to a horizontal magnetic field type MRI. In addition, the embodiment can be also applied to a nuclear magnetic resonance (NMR) analyzing apparatus.

Claim 1:
A superconducting wire comprising:
a MgB<NUM> filament (<NUM>),
characterised in that a number density of voids (<NUM>) each having a major axis of <NUM> or larger is <NUM> to <NUM>-<NUM> on a longitudinal section of the superconducting wire, and
in that an average value of angles formed between the major axis of each of the voids (<NUM>) and the longitudinal axis of the superconducting wire is <NUM> degrees or larger and <NUM> degrees or smaller.