The disclosure of Japanese Patent Application No. 2014-183705 and 2015-097526 filed on Sep. 9, 2014 and May 12, 2015 including the specification, drawings and abstract is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to a magnetic compound having a ThMn12 type crystal structure with high anisotropy field and high saturation magnetization, and a method of producing the same.
2. Description of Related Art
The application of a permanent magnet has been spread in a wide range of fields including electronics, information and telecommunications, medical cares, machine tools, and industrial and automotive motors, and the demand for reduction in the amount of carbon dioxide emissions has increased. In such a situation, development of a high-performance permanent magnet has been increasingly expected along with the spread of hybrid vehicles, energy-saving in industrial fields, the improvement of power generation efficiency, and the like.
A Nd—Fe—B magnet which is currently predominant in the market as a high-performance magnet is used as a magnet for a drive motor of a HV/EHV. Recently, it has been required to further reduce the size of a motor and to further increase the output of a motor (to increase the residual magnetization of a magnet). Accordingly, the development of a new permanent magnet material has been progressing.
In order to develop a material having higher performance than a Nd—Fe—B magnet, a study regarding a rare earth element-iron magnetic compound having a ThMn12 type crystal structure has been carried out. For example, Japanese Patent Application Publication No. 2004-265907 (JP 2004-265907 A) proposes a hard magnetic composition which is represented by R(Fe100-y-wCowTiy)xSizAv (wherein R represents one element or two or more elements selected from rare earth elements including Y in which Nd accounts for 50 mol % or higher of the total amount of R; A represents one element or two elements of N and C; x=10 to 12.5; y=(8.3-1.7×z) to 12; z=0.2 to 2.3; v=0.1 to 3; and w=0 to 30) and has a single-layer structure of a phase having a ThMn12 type crystal structure.
In the currently proposed compound which has a NdFe11TiNx composition having a ThMn12 type crystal structure, anisotropy field is high; however, saturation magnetization is lower than that of a Nd—Fe—B magnet and does not reach the level of a magnet material.
The invention provides a magnetic compound having high anisotropy field and high saturation magnetization at the same time.
According to the first aspect of the invention, the following configuration is provided. A magnetic compound represented by the formula (R(1-x)Zrx)a(Fe(1-y)Coy)bTcMdAe (wherein R represents one or more rare earth elements, T represents one or more elements selected from the group consisting of Ti, V, Mo, and W, M represents one or more elements selected from the group consisting of unavoidable impurity elements, Al, Cr, Cu, Ga, Ag, and Au, A represents one or more elements selected from the group consisting of N, C, H, and P, 0≤x≤0.5, 0≤y≤≤0.6, 4≤a≤20, b=100−a−c−d, 0<c<7, 0≤d≤1, and 1≤e≤18), the magnetic compound including a ThMn12 type crystal structure, in which a volume percentage of an α-(Fe,Co) phase is 20% or lower.
In the magnetic compound, 0≤x≤0.3, and 7≤e≤14 may be satisfied.
In the magnetic compound, in the formula, a relationship between x and c may satisfy a region surrounded by 0<c<7, x≥0, c>−38x+3.8 and c>6.3x+0.65.
A method of producing the above-described magnetic compound of the second aspect of the present invention, the method including: a step of preparing molten alloy having a composition represented by the formula (R(1-x)Zrx)a(Fe(1-y)Coy)bTcMd (wherein R represents one or more rare earth elements, T represents one or more elements selected from the group consisting of Ti, V, Mo, and W, M represents one or more elements selected from the group consisting of unavoidable impurity elements, Al, Cr, Cu, Ga, Ag, and Au, 0≤x≤0.5, 0≤y≤0.6, 4≤a≤20, b=100−a−c−d, 0<c<7, and 0≤d≤1); a step of quenching the molten alloy at a rate of 1×102 K/sec to 1×107 K/sec; and a step of crushing solidified alloy, which is obtained by the quenching, and then causing A (A represents one or more elements selected from the group consisting of N, C, H, and P) to penetrate into the crushed alloy.
The method may include a step of performing a heat treatment at 800° C. to 1300° C. for 2 hours to 120 hours after the quenching step.
A rare earth element-containing magnetic compound of the third aspect of the invention including a ThMn12 type crystal structure, in which a lattice constant a of the crystal structure is within a range of 0.850 nm to 0.875 nm, a lattice constant c of the crystal structure is within a range of 0.480 nm to 0.505 nm, a lattice volume of the crystal structure is within a range of 0.351 nm3 to 0.387 nm3, a hexagon A is defined as a six-membered ring centering on a rare earth atom, which is formed of Fe (8i) and Fe(8j) sites, a hexagon B is defined as a six-membered ring which includes Fe (8i) and Fe(8j) sites in which Fe (8i)-Fe (8i) dumbbells form two sides facing each other, a hexagon C is defined as a six-membered ring which is formed of Fe (8j) and Fe(8f) sites and whose center is positioned on a straight line connecting Fe (8i) and a rare earth atom to each other, a length of the hexagon A in a direction of axis a is shorter than 0.611 nm, an average distance between Fe (8i) and Fe (8i) in the hexagon A is 0.254 nm to 0.288 nm, an average distance between Fe (8j) and Fe (8j) in the hexagon B is 0.242 nm to 0.276 nm, and an average distance between Fe (8f) and Fe (8f) facing each other with the center of the hexagon C interposed therebetween in the hexagon C is 0.234 nm to 0.268 nm.
A magnetic powder of the fourth aspect of the present invention which is made of a compound represented by the formula (R(1-x)Zrx)a(Fe(1-y)Coy)bTcMdAe (wherein R represents one or more rare earth elements, T represents one or more elements selected from the group consisting of Ti, V, Mo, and W, M represents one or more elements selected from the group consisting of unavoidable impurity elements, Al, Cr, Cu, Ga, Ag, and Au, A represents one or more elements selected from the group consisting of N, C, H, and P, 0≤x≤0.5, 0≤y≤0.7, 4≤a≤20, b=100−a−c−d, 0<c≤7, 0≤d≤1, and 1≤e≤18), the magnetic powder including a ThMn12 type crystal structure, in which a volume percentage of an α-(Fe,Co) phase is 20% or lower.
According to the invention, in the compound which includes a ThMn12 type crystal structure and is represented by the formula (R(1-x)Zrx)a(Fe(1-y)Coy)bTcMdAe, percentages of magnetic elements including Fe and Co can increase and magnetization can be improved by reducing the T content. In addition, the amount of an α-(Fe,Co) phase deposited during cooling can be reduced by adjusting the cooling rate of molten alloy during the production process, and magnetization can be improved by depositing a large amount of a ThMn12 type crystal. Further, a balance between the sizes of the respective hexagons can be improved and a ThMn12 type crystal structure can be stably obtained by adjusting the sizes of the respective hexagons as defined above in (6).
Features, advantages, and technical and industrial significance of exemplary embodiments of the invention will be described below with reference to the accompanying drawings, in which like numerals denote like elements, and wherein:
Hereinafter, a magnetic compound according to an embodiment of the invention will be described in detail. The magnetic compound according to the embodiment of the invention is represented by the following formula (R(1-x)Zrx)a(Fe(1-y)Coy)bTcMdAe, and each component thereof will be described below.
R represents a rare earth element and is an essential component in the magnetic compound according to the embodiment of the invention to exhibit permanent magnet characteristics. Specifically, R represents one or more elements selected from Y, La, Ce, Pr, Nd, Sm, and Eu, and Pr, Nd, and Sm are preferably used. A mixing amount a of R is 4 at % or higher and 20 at % or lower. When the mixing amount a of R is lower than 4 at %, the deposition of a Fe phase is great, and the volume percentage of the Fe phase after a heat treatment cannot be decreased. When the mixing amount a of R is higher than 20 at %, the amount of a grain boundary phase is excessively large, and thus magnetization cannot be improved.
Zr is efficient in stabilizing a ThMn12 type crystal phase when substituted with a part of rare earth elements. That is, Zr is substituted with R in the ThMn12 type crystal structure to cause shrinkage of a crystal lattice. As a result, when the temperature of an alloy becomes high or when a nitrogen atom or the like is caused to penetrate into a crystal lattice, Zr has an effect of stably maintaining the ThMn12 type crystal phase. On the other hand, strong magnetic anisotropy derived from R is weakened by Zr substitution from the viewpoint of magnetic characteristics. Therefore, it is necessary to determine the Zr content from the viewpoints of the stability and magnetic characteristics of the crystal. However, in the embodiment of the invention, Zr addition is not essential. When the Zr content is 0, the ThMn12 type crystal phase can be stabilized, for example, by adjusting the component composition of an alloy and performing a heat treatment. Therefore, anisotropy field is improved. However, when the amount of Zr substitution is more than 0.5, anisotropy field significantly decreases. It is preferable that the Zr content x satisfies 0≤x≤0.3.
T represents one or more elements selected from the group consisting of Ti, V, Mo, and W.
In the related art, the ThMn12 type crystal structure is formed by adding a large amount of T exceeding the necessary amount to obtain the stabilization effect of T. Therefore, the content ratio of Fe constituting the compound in the alloy decreases, and Fe atoms occupying sites, which have the largest effect on magnetization, are replaced with, for example, Ti atoms, thereby decreasing overall magnetization. In order to improve magnetization, the mixing amount of Ti may be decreased. In this case, however, the stabilization of the ThMn12 type crystal structure deteriorates. In the related art, RFe11Ti is reported as the RFe12-xTix compound, but a compound in which x is lower than 1, that is, Ti is lower than 7 at % has not been reported.
When the amount of Ti which stabilizes the ThMm2 type crystal structure is reduced, the stabilization of the ThMn12 type crystal structure deteriorates, and α-(Fe,Co) which inhibits anisotropy field or coercive force is deposited. According to the embodiment of the invention, the amount of α-(Fe,Co) deposited can be suppressed by controlling the cooling rate of molten alloy; and even when the mixing amount of T decreases, the ThMn12 phase having high magnetic characteristics can be stably formed by adjusting the volume percentage of an α-(Fe,Co) phase in the compound to be a certain value or lower.
The mixing amount of T is lower than 7 at % in which x in the RFe12-xTix compound is lower than 1. When the mixing amount of Ti is 7 at % or higher, the content ratio of Fe constituting the compound decreases, and overall magnetization decreases.
In the compound according to the embodiment of the invention represented by the formula (R(1-x)Zrx)a(Fe(1-y)Coy)bTcMdAe, it is preferable that a relationship between the Zr content x and the T content c satisfies a region (0<c<7, x≥0) surrounded by c>−38x+3.8 and c>6.3x+0.65.
M represents one or more elements selected from the group consisting of unavoidable impurity elements, Al, Cr, Cu, Ga, Ag, and Au. The unavoidable impurity elements refer to elements incorporated into raw materials or elements incorporated during the production process, and specific examples thereof include Si and Mn. M contributes to the inhibition of grain growth of the ThMn12 type crystal and the viscosity and melting point of a phase (for example, a grain boundary phase) other than the ThMn12 type crystal but is not essential in the invention. A mixing amount d of M is lower than 1 at %. When the mixing amount d of M is higher than 1 at %, the content ratio of Fe constituting the compound in the alloy decreases, and overall magnetization decreases.
A represents one or more elements selected from the group consisting of N, C, H, and P. A can be caused to penetrate into a crystal lattice of the ThMn12 phase to expand the lattice in the ThMn12 phase such that both characteristics of anisotropy field and saturation magnetization can be improved. A mixing amount e of A is 1 at % or higher and 18 at % or lower. When the mixing amount e of A is lower than 1 at %, the effects cannot be exhibited. When the mixing amount e of A is higher than 18 at %, the content ratio of Fe constituting the compound in the alloy decreases, a part of the ThMn12 phase is decomposed due to deterioration in the stability of the ThMn12 phase, and overall magnetization decreases. The mixing amount e of A is preferably 7≤e≤14.
A remainder of the compound according to the embodiment of the invention other than the above-described elements is Fe, and a part of Fe may be substituted with Co. Co can be substituted with Fe to cause an increase in spontaneous magnetization according to the Slater-Pauling rule such that both characteristics of anisotropy field and saturation magnetization can be improved. However, when the amount of Co substitution is higher than 0.6, the effects cannot be exhibited. In addition, when Fe is substituted with Co, the Curie point of the compound increases, and thus an effect of suppressing a decrease in magnetization at a high temperature can be obtained.
The magnetic compound according to the embodiment of the invention is represented by the above-described formula and has a ThMn12 type crystal structure. This ThMn12 type crystal structure is tetragonal and shows peaks at 2θ values of 29.801°, 36.554°, 42.082°, 42.368°, and 43.219° (±0.5°) in the XRD measurement results. Further, in the magnetic compound according to the embodiment of the invention, a volume percentage of an α-(Fe,Co) phase is 20% or lower. This volume percentage is calculated by embedding a sample with a resin, polishing the sample, observing the sample with OM or SEM-EDX, and obtaining an area ratio of the α-(Fe,Co) phase in a cross-section by image analysis. Here, when it is assumed that the structure is not randomly oriented, the following relational expression of A≅V is established between the average area ratio A and the volume percentage V. Therefore, in the embodiment of the invention, the area ratio of the α-(Fe,Co) phase measured as described above is set as the volume percentage.
As described above, in the magnetic compound according to the embodiment of the invention, magnetization can be improved by reducing the T content as compared to a RFe11Ti type compound of the related art. In addition, both characteristics of anisotropy field and saturation magnetization can be significantly improved by reducing the volume percentage of the α-(Fe,Co) phase.
(Production Method)
Basically, the magnetic compound according to the embodiment of the invention can be produced using a production method of the related art such as a mold casting method or an arc melting method. However, in the method of the related art, a large amount of the stable phase (α-(Fe,Co) phase) other than the ThMn12 is deposited, and anisotropy field and saturation magnetization decrease. Here, focusing on the fact that a temperature at which the ThMn12 type crystal is deposited is lower than a temperature at which α-(Fe,Co) is deposited, in the embodiment of the invention, molten alloy is quenched at a rate of 1×102 K/sec to 1×107 K/sec such that the temperature of the molten alloy is prevented from being maintained in a region near the temperature at which α-(Fe,Co) is deposited for a long period of time. As a result, the deposition of α-(Fe,Co) can be reduced and a large amount of the ThMn12 type crystal can be produced.
As a cooling method, for example, molten alloy can be cooled at a predetermined rate using an apparatus 10 shown in
Here, the tundish 13 is made of a ceramic, can temporarily store the molten alloy 12 which is continuously supplied from the melting furnace 11 at a predetermined flow rate, and can rectify the flow of the molten alloy 12 to the cooling roller 14. In addition, the tundish 13 has a function of adjusting the temperature of the molten alloy 12 immediately before the molten alloy 12 reaches the cooling roller 14.
The cooling roller 14 is formed of a material having high thermal conductivity such as copper or chromium, and, for example, the roller surface is plated with chromium to prevent corrosion with the molten alloy having a high temperature. This roller can be rotated by a drive device (not shown) at a predetermined rotating speed in a direction indicated by an arrow. By controlling the rotating speed, the cooling rate of the molten alloy can be controlled to be 1×102 K/sec to 1×107 K/sec.
The molten alloy 12 which is cooled and solidified on the outer periphery of the cooling roller 14 is peeled off from the cooling roller 14 as flaky solidified alloy 15. The solidified alloy 15 is crushed and collected by a collection device.
Further, the method according to the embodiment of the invention may further include a step of performing a heat treatment on particles obtained in the above-described step at 800° C. to 1300° C. for 2 hours to 120 hours. Due to this heat treatment, the ThMn12 phase is made to be homogeneous, and both characteristics of anisotropy field and saturation magnetization are further improved.
The collected alloy is crushed, and A (A represents one or more elements selected from the group consisting of N, C, H, and P) is caused to penetrate into the alloy. Specifically, when nitrogen is used as A, the alloy is nitrided by performing a heat treatment thereon using nitrogen gas or ammonia gas as a nitrogen source at a temperature of 200° C. to 600° C. for 1 hour to 24 hours. When carbon is used as A, the alloy is carbonized by performing a heat treatment thereon using C2H2 (CH4, C3H8, or CO) gas or thermally decomposed gas of methanol as a carbon source at a temperature of 300° C. to 600° C. for 1 hour to 24 hours. In addition, solid carburizing using carbon powder or carburizing using molten salt such as KCN or NaCN can be performed. In regard to H and P, typical hydrogenation and phosphorization can be performed.
(Crystal Structure)
The magnetic compound according to the embodiment of the invention is a rare earth element-containing magnetic compound having a ThMn12 type tetragonal crystal structure shown in
As shown in
Further, the magnetic powder according to the embodiment of the invention is represented by the formula (R(1-x)Zrx)a(Fe(1-y)Coy)bTcMdAe and includes a ThMn12 type crystal structure, in which a volume percentage of an α-(Fe,Co) phase is 20% or lower. In the above-described formula, R represents one or more rare earth elements, T represents one or more elements selected from the group consisting of Ti, V, Mo, and W, M represents one or more elements selected from the group consisting of unavoidable impurity elements, Al, Cr, Cu, Ga, Ag, and Au, A represents one or more elements selected from the group consisting of N, C, H, and P, b=100−a−c−d, 0<c≤7, 0≤d≤1, and 1≤e≤18.
Molten alloys for preparing compounds having a composition shown in
Molten alloy for preparing a compound having a composition shown in
As clearly seen from the results of
Molten alloys for preparing compounds having a composition shown in
Molten alloys for preparing compounds having a composition shown in
Molten alloys for preparing compounds having a composition shown in
It is considered from the above results that, due to quenching, the α-(Fe,Co) phase was refined, the amount thereof deposited was reduced, and the entire structure was refined and homogeneously dispersed; as a result, characteristics were further improved. In addition, it is considered that, by further performing the heat treatment after cooling, the homogenization of the refined structure progressed, and the amount of the α-(Fe,Co) phase was reduced; as a result, characteristics were improved. In this way, even when the Ti content was reduced from 7 at % to 4 at %, due to the quenching treatment and the homogenization heat treatment, the deposition of the α-(Fe,Co) phase was suppressed, and anisotropy field was exhibited as in the related art. As a result, a magnetic compound having a ThMn12 type crystal structure in which high characteristics of anisotropy field and saturation magnetization were realized was able to be prepared.
Molten alloys for preparing compounds having a composition shown in
As can be seen from the experiment results, anisotropy field exhibits high values without being substantially affected by the Co substitution ratio. On the other hand, saturation magnetization was the maximum at Co substitution ratio=0.3 and decreased at y=0.7 or higher. Further, the Curie point increased along with an increase in Co content (when y=0.5 or higher, the Curie point was not able to be measured due to the limitation of the apparatus). Accordingly, it was found that a range of 0≤y≤0.7 is preferable in regard to Co.
Here, in the crystal structure, hexagons A, B, and C were defined as follows: the hexagon A was defined as a six-membered ring centering on a rare earth atom R, which is formed of Fe (8i) and Fe(8j) sites; the hexagon B was defined as a six-membered ring which included Fe (8i) and Fe(8j) sites in which Fe (8i)-Fe (8i) dumbbells formed two sides facing each other; and the hexagon C was defined as a six-membered ring which is formed of Fe (8j) and Fe(8f) sites and whose center was positioned on a straight line connecting Fe (8i) and a rare earth atom to each other. At this time, it was found from
Molten alloys for preparing compounds having a composition shown in
It was found from the results of crystal structure analysis using XRD in
Molten alloys for preparing compounds having a composition shown in
It was found from the results of
Molten alloys for preparing compounds having a composition shown in
It was found that the lattice constant was increased in directions of axes a and c along with an increase in N content. In addition, it was found that nitrogen was introduced in amount of up to 15.4 at % without breaking the crystal structure. It was found as described above that saturation magnetization and anisotropy field were increased along with an increase in N content.
Number | Date | Country | Kind |
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2014-183705 | Sep 2014 | JP | national |
2015-097526 | May 2015 | JP | national |
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Number | Date | Country |
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H06-235051 | Aug 1994 | JP |
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Hirayama et al., “NdFe12Nx Hard-Magnetic Compound with High Magnetization and Anisotropy Field,” Science Direct, Scripta Materialia, 2015, vol. 95, pp. 70-72. |
Number | Date | Country | |
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20160071635 A1 | Mar 2016 | US |