CN111261351A - High-coercivity SmCo5FeCo nano composite permanent magnetic material and preparation method thereof - Google Patents

High-coercivity SmCo5FeCo nano composite permanent magnetic material and preparation method thereof Download PDF

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CN111261351A
CN111261351A CN202010136812.4A CN202010136812A CN111261351A CN 111261351 A CN111261351 A CN 111261351A CN 202010136812 A CN202010136812 A CN 202010136812A CN 111261351 A CN111261351 A CN 111261351A
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smco
magnetic material
permanent magnetic
nano composite
alloy
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CN111261351B (en
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安士忠
李孝森
李武会
徐盼盼
殷婷
朱雁风
任凤章
宋克兴
马峥
吕贵红
肖滕龙
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Henan University of Science and Technology
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    • H01F1/00Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
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    • H01F1/03Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity
    • H01F1/032Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials
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    • H01F1/04Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity of hard-magnetic materials metals or alloys
    • H01F1/047Alloys characterised by their composition
    • H01F1/053Alloys characterised by their composition containing rare earth metals
    • H01F1/055Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5
    • H01F1/0551Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 in the form of particles, e.g. rapid quenched powders or ribbon flakes
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    • H01F1/03Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity
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    • H01F1/00Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
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    • H01F41/02Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets
    • H01F41/0253Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing permanent magnets
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    • H01F41/0253Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing permanent magnets
    • H01F41/0293Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing permanent magnets diffusion of rare earth elements, e.g. Tb, Dy or Ho, into permanent magnets

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Abstract

The invention belongs to the technical field of permanent magnet materials, and particularly relates to high-coercivity SmCo5a/FeCo nano composite permanent magnetic material and a preparation method thereof. SmCo of the present invention5the/FeCo nano composite permanent magnetic material is prepared from SmCo5α -Fe and SmCo5Mixing hard magnetic phase stabilizing components and performing thermal deformation treatment to obtain the SmCo5The hard magnetic phase stabilizing component is SmNi alloy and/or SmZn alloy, and the α -Fe is SmCo5And α -Fe 20-50 wt.% (SmCo)5The hard magnetic phase stabilizing component can stabilize SmCo5Of the present invention, thus the SmCo of the present invention5the/FeCo nano composite permanent magnetic material has high coercive force which is 4-6 times of the coercive force of a composite material which does not contain SmNi or SmZn alloy and is prepared under the same condition.

Description

High-coercivity SmCo5FeCo nano composite permanent magnetic material and preparation method thereof
Technical Field
The invention belongs to the technical field of permanent magnet materials, and particularly relates to high-coercivity SmCo5a/FeCo nano composite permanent magnetic material and a preparation method thereof.
Background
SmCo5The hard magnetic material has a strong magnetocrystalline anisotropy field (40T) and a high coercive force (5-7T can be achieved in a laboratory), but the saturation magnetization intensity is not high. While soft magnetic phases such as Fe, Co and FeCo alloys, etc., having high saturation magnetization, are compared to SmCo5The nano-composite material with the characteristics of high saturation magnetization, high remanence and high coercivity can be obtained hopefully in nano-size composite. But soft magnetic phase and SmCo5SmCo formed by recombination5SmCo when the content of the soft magnetic phase in the soft magnetic phase two-phase nano composite material is higher (more than or equal to 20 percent)5Compatibility is easy to convert into SmCo3、SmCo7And Sm2Co17A phase with lower iso-magnetocrystalline anisotropy, thereby enabling SmCo5The coercive force of the soft magnetic phase two-phase nano composite material is lower.
Disclosure of Invention
Objects of the inventionIs to provide a high coercive force SmCo5The composite permanent magnetic material has high coercive force.
The object of the present invention is to provide a high coercive force SmCo5A preparation method of a/FeCo nano composite permanent magnetic material.
In order to achieve the purpose, the invention adopts the technical scheme that:
high-coercivity SmCo5a/FeCo nano composite permanent magnetic material made of SmCo5α -Fe and SmCo5Mixing hard magnetic phase stabilizing components, compacting, and thermally deforming to obtain SmCo5The hard magnetic phase stabilizing component is SmNi alloy and/or SmZn alloy, and the α -Fe is SmCo5And α -Fe accounting for 20-50% of the total mass.
SmCo5Being a hard magnetic phase, SmCo5Sm atoms and Ni atoms or Zn atoms in the hard magnetic phase stabilizing component enter SmCo by diffusion5In the crystal lattice of (2), SmCo can be improved5Stability of crystal structure, thereby suppressing SmCo5Phase inversion, so that the SmCo of the present invention5the/FeCo nano composite permanent magnetic material has higher coercive force. The coercive force of the nano composite material of the invention is prepared under the same condition and does not contain SmCo54-6 times of the composite material of the hard magnetic phase stabilizing component.
The magnetic properties of the nanocomposite permanent magnetic material of the invention, the SmCo, are further optimized by adjusting the quality of the raw materials used5The hard magnetic phase stabilizing component has a mass of SmCo5α -Fe and SmCo52.5-10% of the total mass of the hard magnetic phase stabilizing components; the mass percentage of Sm in the SmNi and SmZn alloy is 50-90%, and the balance is Ni or Zn. Further preferably, the SmCo5The hard magnetic phase stabilizing component has a mass of SmCo5α -Fe and SmCo52.5-7.5% of the total mass of the hard magnetic phase stabilizing components; the mass percentage of Sm in the SmNi and SmZn alloy is 83-88%, and the balance is Ni or Zn. When the Sm content in the SmNi and SmZn alloy is too low, the alloy can be used for SmCo5The phase stabilization effect is poor; meanwhile, a small amount of Ni or Zn in the alloy can promoteDiffusion and stabilization of atoms of SmCo5And (4) forming a phase.
High coercivity SmCo of the invention5The preparation method of the/FeCo nano composite permanent magnetic material adopts the technical scheme that:
the SmCo with high coercive force5The preparation method of the/FeCo nano composite permanent magnetic material comprises the following steps: SmCo is mixed5α -Fe and SmCo5Uniformly mixing the hard magnetic phase stabilizing components to obtain a mixture; and (3) pressing and forming the mixture, and then carrying out thermal deformation treatment.
The preparation method of the invention prepares SmCo5The hard magnetic phase stabilizing component is uniformly introduced into the hard magnetic phase SmCo5In order to stabilize the hard magnetic phase SmCo5The function of the structure. SmCo prepared by adopting preparation method of the invention5the/FeCo nano composite permanent magnetic material has higher compactness, and the main phase of the hard magnetic phase is SmCo with a strong magnetocrystalline anisotropy field5The phase has higher coercive force and better comprehensive magnetic performance. The preparation process is simple and feasible, and the cost is low.
The compactness of the nanocomposite material of the invention is further improved and the production time is shortened by optimizing the conditions of thermal Deformation treatment, preferably, the temperature (T) during the thermal Deformation treatment is 600-900 ℃, the Deformation amount (Reduction) is 30-90%, and the Deformation rate (Deformation rate) is 5%/min-100%/min. More preferably, the temperature during the thermal deformation treatment is 600 ℃, the deformation amount is 60%, and the deformation rate is 30%/min to 50%/min.
The SmNi or SmZn alloy being sized to enable the SmCo to be used5Preferably, SmCo is matched to the size of the α -Fe feedstock5Preferably, the SmNi or SmZn alloy is alloy rapid-hardening thin strip, the thickness of the alloy rapid-hardening thin strip is 10-200 mu m, the alloy crystal grains in the alloy rapid-hardening thin strip are fine, and the alloy rapid-hardening thin strip is beneficial to alloy and SmCo5And α -Fe, compared with cast ingot, the alloy quick-setting thin strip has stronger brittleness, is easier to break and is convenient to mix uniformlyAnd mixing is uniform, and mixing time is saved.
Preferably, SmCo5α -Fe and powder with particle size less than 180 μm SmCo5The particle diameter of (B) may be the same as or different from that of α -Fe.
In order to improve the mixing uniformity of the three raw materials, the mixing is ball milling mixing, the ball milling time is 4-24 hours, and the rotating speed is 300-700 r/min.
The pressure used during the compression molding is 0.8-1.2 GPa, the die used during the compression molding is stainless steel, and the temperature during the compression molding is room temperature. The pressing forming specifically comprises the following steps: pressing the mixture into thin slices (thickness/diameter is less than 0.4), and filling the thin slices into a steel pipe to obtain a green compact. The compact is used for subsequent hot deformation treatment.
High coercive force SmCo in the present invention5In the preparation method of the/FeCo nano composite permanent magnetic material, mixing, compression molding and thermal deformation treatment are carried out in a protective atmosphere. Preferably, the protective atmosphere is an argon atmosphere.
Drawings
FIG. 1 shows SmCo of the present invention5A preparation flow chart of a/FeCo nano composite permanent magnetic material;
FIG. 2 is the initial magnetization curve and hysteresis loop of the nanocomposite permanent magnetic material of example 1 of the present invention and the nanocomposite material of comparative example 1;
FIG. 3 is the initial magnetization curve and hysteresis loop of the nanocomposite permanent magnetic material of example 2 of the present invention and the nanocomposite material of comparative example 1;
FIG. 4 is the initial magnetization curve and hysteresis loop for the nanocomposite permanent magnetic material of example 3 of the present invention and the nanocomposite material of comparative example 1;
FIG. 5 is the initial magnetization curve and hysteresis loop for the nanocomposite permanent magnetic material of example 4 of the present invention and the nanocomposite material of comparative example 1;
FIG. 6 is a TEM (a) and a selected area electron diffraction pattern (b) of the nanocomposite of comparative example 1 of the present invention;
FIG. 7 is a TEM (a) and selected area electron diffraction pattern (b) of a nanocomposite permanent magnetic material of example 1 of the present invention;
FIG. 8 is a TEM (a) and selected area electron diffraction pattern (b) of a nanocomposite permanent magnetic material of example 3 of the present invention;
FIG. 9 is an XRD pattern of the nanocomposite permanent magnetic material of example 1 of the present invention and the nanocomposite material of comparative example 1;
fig. 10 is an XRD pattern of the nanocomposite permanent magnetic material of example 3 of the present invention and the nanocomposite material of comparative example 1.
Detailed Description
The present invention will be further described with reference to the following specific examples.
SmCo used in the following examples5The powder is prepared by the following method: calculating the simple substances Sm and Co with the purity of more than 99.5 percent according to the stoichiometric ratio of 1:5, adding more Sm with the mass of 5 percent of the simple substance Sm calculated according to the stoichiometric ratio during smelting, and smelting to obtain SmCo5Ingot casting SmCo5And (4) crushing the cast ingot, and sieving the crushed cast ingot with a 80-mesh sieve to obtain the product.
High coercive force SmCo5Examples of/FeCo nanocomposite permanent magnetic materials
Example 1
High coercive force SmCo of this example5the/FeCo nano composite permanent magnetic material is prepared from SmCo5Mixing the powder and α -Fe powder (powder sieved by a 80-mesh sieve and a SmNi alloy rapid-hardening thin strip (the thickness is 10-50 mu m)) and then carrying out thermal deformation treatment to obtain the alloy, wherein the α -Fe is SmCo 520 percent of powder and α -Fe powder by mass, and the mass of the SmNi alloy rapid-hardening thin strip is SmCo52.5 percent of the total mass of the powder, α -Fe powder and the SmNi alloy rapid-hardening thin strip, 83 percent of Sm in the SmNi alloy rapid-hardening thin strip and the balance of Ni.
Example 2
High coercive force SmCo of this example5the/FeCo nano composite permanent magnetic material is prepared from SmCo5Mixing the powder, α -Fe powder (powder sieved by a 80-mesh sieve) and a SmNi alloy rapid-hardening thin strip (the thickness is 30-90 mu m), and performing thermal deformation treatment to obtain the alloy, wherein the α -Fe is SmCo in mass520 percent of powder and α -Fe powder by mass, and the mass of the SmNi alloy rapid-hardening thin strip is SmCo5Powder α -Fe powderAnd the SmNi alloy rapid-hardening thin strip accounts for 7.5 percent of the total mass of the SmNi alloy rapid-hardening thin strip; the mass percent of Sm in the SmNi alloy rapid-hardening thin strip is 83 percent, and the balance is Ni.
Example 3
High coercive force SmCo of this example5the/FeCo nano composite permanent magnetic material is prepared from SmCo5Mixing the powder, α -Fe powder (powder sieved by a 80-mesh sieve) and a SmZn alloy rapid-hardening thin strip (the thickness is 80-150 mu m), and performing thermal deformation treatment to obtain the alloy, wherein the α -Fe is SmCo in mass520 percent of powder and α -Fe powder by mass, and the mass of the SmCo alloy rapid-hardening thin strip is SmCo 55 percent of the total mass of the powder, α -Fe powder and the SmZn alloy rapid-hardening thin strip, 88 percent of Sm in the SmZn alloy rapid-hardening thin strip and the balance of Zn.
Example 4
High coercive force SmCo of this example5the/FeCo nano composite permanent magnetic material is prepared from SmCo5Mixing the powder, α -Fe powder (powder sieved by a 80-mesh sieve) and a SmZn alloy rapid-hardening thin strip (the thickness is 140-200 mu m), and performing thermal deformation treatment to obtain the alloy, wherein the α -Fe is SmCo in mass520 percent of powder and α -Fe powder by mass, and the mass of the SmCo alloy rapid-hardening thin strip is SmCo57.5 percent of the total mass of the powder, α -Fe powder and the SmZn alloy rapid-hardening thin strip, 88 percent of Sm in the SmZn alloy rapid-hardening thin strip and the balance of Zn.
Example 5
High coercive force SmCo of this example5the/FeCo nano composite permanent magnetic material is prepared from SmCo5Mixing the powder, α -Fe powder (powder sieved by a 80-mesh sieve) and a SmZn alloy rapid-hardening thin strip (the thickness is 10-80 mu m), and performing thermal deformation treatment to obtain the alloy, wherein the α -Fe is SmCo in mass530 percent of powder and α -Fe powder by mass, and the mass of the SmCo alloy rapid-hardening thin strip is SmCo 510 percent of the total mass of the powder, α -Fe powder and the SmZn alloy rapid-hardening thin strip, 50 percent of Sm in the SmZn alloy rapid-hardening thin strip and the balance of Zn.
Example 6
High coercive force SmCo of this example5the/FeCo nano composite permanent magnetic material is prepared from SmCo5Powder, α -Fe powder (powder sieved by a 80-mesh sieve) and a SmZn alloy rapid-hardening thin strip (thickness)70-160 μm) and thermally deforming the mixture, wherein α -Fe is SmCo 540 percent of powder and α -Fe powder by mass, and the mass of the SmCo alloy rapid-hardening thin strip is SmCo 510 percent of the total mass of the powder, α -Fe powder and the SmZn alloy rapid-hardening thin strip, 70 percent of Sm in the SmZn alloy rapid-hardening thin strip and the balance of Zn.
Example 7
High coercive force SmCo of this example5the/FeCo nano composite permanent magnetic material is prepared from SmCo5Mixing the powder, α -Fe powder (powder sieved by a 80-mesh sieve) and a SmZn alloy rapid-hardening thin strip (the thickness is 120-200 mu m), and performing thermal deformation treatment to obtain the alloy, wherein the α -Fe is SmCo in mass550 percent of powder and α -Fe powder by mass, and the mass of the SmCo alloy rapid-hardening thin strip is SmCo 510 percent of the total mass of the powder, α -Fe powder and the SmZn alloy rapid-hardening thin strip, 90 percent of Sm in the SmZn alloy rapid-hardening thin strip and the balance of Zn.
Second, high coercive force SmCo5Examples of the preparation method of/FeCo nanocomposite permanent magnetic materials
High coercivity SmCo of the invention5The preparation process flow of the/FeCo nano composite permanent magnetic material is shown in figure 1, and comprises the following steps: firstly, the raw material (SmCo)5+ α -Fe + (SmNi or SmZn)) is subjected to Ball milling and mixing (Ball milling) to obtain mixed powder (Milled powder), the mixed powder is Amorphous powder (Amorporus + FeCo) containing FeCo phase, then the mixed powder is placed in a stainless Steel mould to be pressed and formed (consolidation), in order to ensure the density, firstly the mixed powder is pressed to obtain a sheet (the thickness/the diameter is less than 0.4), then the sheet is placed in a stainless Steel sleeve (Steel Capsule or Capsule) to obtain a compact, then the compact is subjected to Hot deformation treatment (Hot deformation), and after the Hot deformation treatment is finished, mechanical processing (Machining) is carried out to ensure that the material (Sample) falls off from the stainless Steel sleeve, and in order to reduce the oxidation, the Ball milling, the pressing and the Hot deformation are carried out under the protection of argon (the oxygen content is less than 5 ppm).
Example 8
The preparation process of this example gives a product corresponding to the high coercivity SmCo in example 15the/FeCo nano composite permanent magnetic material comprises the following steps:
(1) SmCo is mixed5Ball-milling the powder, α -Fe powder and the SmNi alloy rapid-hardening thin strip in an all-directional planetary ball mill for 6 hours at the rotating speed of 500r/min by using argon as a ball-milling medium to obtain mixed powder;
the SmNi alloy rapid-hardening thin strip is prepared by the following method: firstly, carrying out electric arc melting to obtain a SmNi alloy cast ingot, and then preparing the SmNi alloy cast ingot into a quick-setting thin strip on vacuum quick-quenching equipment, wherein the specific process comprises the following steps: vacuum degree higher than 1 x 10-3Under the condition of Pa, the alloy ingot is heated and melted and then rapidly sprayed onto a water-cooled copper wheel with the rotating speed of 40m/s under pressure.
(2) Loading the mixed powder into a stainless steel die in an argon atmosphere, then applying a pressure of 1GPa to the powder along the axial direction at room temperature, firstly pressing to obtain a sheet (the thickness/diameter is 0.2-0.3), and then loading the sheet into a stainless steel sleeve to obtain a pressed compact (the outside is the stainless steel sleeve); and then carrying out thermal deformation treatment along the axial direction, wherein the thermal deformation temperature is 600 ℃, the deformation amount is 60%, the deformation rate is 30%/min, and removing the stainless steel sleeve after the thermal treatment is finished.
Example 9
The preparation process of this example gives a product corresponding to the high coercivity SmCo of example 25The specific process of the/FeCo nano composite permanent magnetic material is the same as that of example 8.
Example 10
The preparation process of this example gives a product corresponding to the high coercivity SmCo in example 35the/FeCo nano composite permanent magnetic material comprises the following steps:
(1) SmCo is mixed5Ball-milling the powder, α -Fe powder and the SmZn alloy rapid-hardening thin strip in an all-directional planetary ball mill for 6 hours at the rotating speed of 500r/min by using argon as a ball-milling medium to obtain mixed powder;
the SmZn alloy rapid-hardening thin strip is prepared by the following method: firstly, carrying out electric arc melting to obtain a SmZn alloy cast ingot, and then preparing the SmZn alloy cast ingot into a quick-setting thin strip on vacuum quick-quenching equipment, wherein the specific process comprises the following steps: vacuum degree higher than 1 x 10-3Under the condition of Pa, the alloy ingot is heated and melted and then rapidly sprayed onto a water-cooled copper wheel with the rotating speed of 40m/s under pressure。
(2) Loading the mixed powder into a stainless steel die in an argon atmosphere, then applying a pressure of 1GPa to the powder along the axial direction at room temperature, firstly pressing to obtain a sheet (the thickness/diameter is 0.2-0.3), and then loading the sheet into a stainless steel sleeve to obtain a pressed compact (the outside is the stainless steel sleeve); and then carrying out thermal deformation treatment along the axial direction, wherein the thermal deformation temperature is 600 ℃, the deformation amount is 60%, the deformation rate is 50%/min, and removing the stainless steel sleeve after the thermal treatment is finished.
Example 11
The preparation process of this example gives a product corresponding to the high coercivity SmCo in example 45The specific process of the/FeCo nano composite permanent magnetic material is basically the same as that of the example 10, and the difference is only that: the deformation rate in the thermal deformation in the step (2) is 30%/min.
Example 12
The preparation process of this example produced a product corresponding to the high coercivity SmCo of example 55The specific process of the/FeCo nano composite permanent magnetic material is basically the same as that of the example 10, and the difference is only that: the time for ball milling in the step (1) is 4h, and the rotating speed is 700 r/min; in the step (2), a compact is obtained by applying a pressure of 1.2GPa to the powder, the temperature during thermal deformation is 700 ℃, the deformation amount is 30%, and the deformation rate is 5%/min.
Example 13
The preparation process of this example produced a product corresponding to the high coercivity SmCo of example 65The specific process of the/FeCo nano composite permanent magnetic material is basically the same as that of the example 10, and the difference is only that: the time for ball milling in the step (1) is 12 hours, and the rotating speed is 600 r/min; in the step (2), a compact is obtained by applying a pressure of 1.1GPa to the powder, the temperature during thermal deformation is 800 ℃, the deformation amount is 60 percent, and the deformation rate is 80 percent/min.
Example 14
The preparation process of this example produced a product corresponding to the high coercivity SmCo of example 75The specific process of the/FeCo nano composite permanent magnetic material is basically the same as that of the example 10, and the difference is only that: the time for ball milling in the step (1) is 24 hours, and the rotating speed is 300 r/min; step (2) of adding the powderA green compact was obtained by applying a pressure of 0.8GPa, the temperature at the time of thermal deformation was 900 ℃, the deformation was 90%, and the deformation rate was 100%/min.
Thirdly, comparison example: without SmNi or SmZn alloys
Comparative example 1
SmCo of this comparative example5/soft magnetic phase nano composite material made of SmCo5Mixing the powder with α -Fe powder, and thermally deforming to obtain the final product, wherein α -Fe is SmCo 520% by mass of the powders and α -Fe powder, the preparation method was substantially the same as in example 8 except that SmNi alloy or SmZn alloy was not added during ball milling in step (1).
SmCo of this comparative example5When the soft magnetic phase nanocomposite material is prepared, a sample is prepared in the same batch as the samples in the embodiments 8-9, and is marked as a sample without introduction of the SmNi alloy (without SmNi); then, another sample was prepared in the same batch as the samples in examples 10 to 14, and was labeled as a sample (withoutSmZn) into which SmZn alloy was not introduced.
Comparative example 2
SmCo of this comparative example5/soft magnetic phase nano composite material made of SmCo5Mixing the powder with α -Fe powder, and thermally deforming to obtain the final product, wherein α -Fe is SmCo 530% by mass of the powder and α -Fe powder, the preparation method was substantially the same as in example 12 except that SmNi alloy or SmZn alloy was not added during ball milling in step (1).
Comparative example 3
SmCo of this comparative example5/soft magnetic phase nano composite material made of SmCo5Mixing the powder with α -Fe powder, and thermally deforming to obtain the final product, wherein α -Fe is SmCo 540% by mass of the powders and α -Fe powder, the preparation method was substantially the same as in example 13 except that SmNi alloy or SmZn alloy was not added during the ball milling in the step (1).
Comparative example 4
SmCo of this comparative example5/soft magnetic phase nano composite material made of SmCo5Mixing the powder with α -Fe powder, and thermally deforming to obtain the final product, wherein α -Fe is SmCo5Powders and α -Fe powder by mass50%, the specific preparation method is basically the same as that of example 14, except that: and (2) adding SmNi alloy or SmZn alloy during ball milling in the step (1).
Fourth, test example
Test example 1
The magnetic properties of the nanocomposite permanent magnet materials of examples 1-7 and the nanocomposite materials of comparative examples 1-4 were tested, and the specific test procedure was as follows: at room temperature, testing an initial magnetization curve of 0-3T, and then measuring a hysteresis loop under the condition of 3T-3T, wherein a sample during testing is a cylinder with phi of 3mm multiplied by 3, and the sample during testing is along the axial direction of the cylinder. The initial magnetization curves and hysteresis loops of the materials of examples 1 to 4 and comparative example 1 are shown in fig. 2 to 5, respectively.
FIG. 2 is a hysteresis loop of a nanocomposite permanent magnetic material of example 1 of the present invention (with 2.5% SmNi) and a nanocomposite material of comparative example 1 (with without SmNi); FIG. 3 is a hysteresis loop of a nanocomposite permanent magnetic material of example 2 of the present invention (with 7.5% SmNi) and a nanocomposite material of comparative example 1 (with without SmNi); FIG. 4 is a hysteresis loop of a nanocomposite permanent magnetic material of example 3 of the present invention (with 5% SmZn) and a nanocomposite material of comparative example 1 (with without SmZn); FIG. 5 is a hysteresis loop of the nanocomposite permanent magnetic material of example 4 of the present invention (with 7.5% SmZn) and the nanocomposite material of comparative example 1 (wthout SmZn).
As can be seen from fig. 2 to 5, the coercive force of the nanocomposite of comparative example 1 when the SmNi alloy or the SmZn alloy was not introduced was only 1.24kOe (sample to which the SmNi alloy was not introduced) and 1.54kOe (sample to which the SmZn alloy was not introduced) (the sample to which the SmNi alloy was not introduced and the sample to which the SmZn alloy was not introduced were not prepared in the same lot, and thus the coercive force was different, but within the error allowance range). The coercive force of the nano composite permanent magnetic material in the embodiment 1 is 5.13kOe, which is 4.1 times of that of the nano composite material in the comparative example 1; the coercive force of the nanocomposite permanent magnetic material of example 2 was 7.29kOe, which was 5.9 times that of the nanocomposite material of comparative example 1; the coercive force of the nanocomposite permanent magnetic material of example 3 was 6.88kOe, which was 4.5 times that of the nanocomposite material of comparative example 1; the coercivity of the nanocomposite permanent magnetic material of example 4 was 8.37kOe, which is 5.4 times that of the nanocomposite material of comparative example 1. Meanwhile, as can be seen from fig. 2 to 5, the residual magnetization of the nanocomposite material of the present invention is also improved.
The test results also show that: the coercivity of the nanocomposite permanent magnetic material in example 5 was 5.08kOe, while the coercivity of the nanocomposite material in comparative example 2 was 1.02 kOe; the coercivity of the nanocomposite permanent magnetic material in example 6 was 4.98kOe, while the coercivity of the nanocomposite material in comparative example 3 was 0.96 kOe; the coercivity of the nanocomposite permanent magnetic material in example 7 was 4.57kOe, while the coercivity of the nanocomposite material in comparative example 4 was 0.89 kOe.
Test example 2
TEM tests were performed on the nanocomposite permanent magnetic materials in examples 1 and 3 and the nanocomposite material in comparative example 1, and the test results are shown in FIGS. 6 to 8. Wherein FIG. 6 is a TEM (a) and a selected area electron diffraction pattern (b) of the nanocomposite of comparative example 1, the results show that the material has a grain size of about 10nm, as represented by Sm2Co17FIG. 7 is a TEM (a) and a selected area electron diffraction pattern (b) of the nanocomposite permanent magnetic material of example 1, showing a grain size of about 10nm, consisting of SmCo5、Sm2Co17FIG. 8 is a TEM (a) and selected area electron diffraction pattern (b) of the nanocomposite permanent magnetic material of example 3, showing a grain size of about 10nm, as defined by SmCo5、Sm2Co17And α -FeCo phase.
The test results show that the SmNi or SmZn alloy has small influence on the grain size of the material after being introduced and can stabilize SmCo5And (4) phase(s).
Test example 3
XRD tests were performed on the nanocomposite permanent magnetic materials of examples 1 and 3 and the nanocomposite material of comparative example 1, and the results are shown in fig. 9 and 10.
FIG. 9 is an XRD pattern of the nanocomposite permanent magnetic material of example 1 (with 2.5 wt.% SmNi) and the nanocomposite material of comparative example 1 (with SmNi out);fig. 10 is an XRD pattern in the nanocomposite permanent magnetic material of example 3 (with 5 wt.% SmZn) and the nanocomposite material of comparative example 1 (with smot SmZn). XRD test results show that the main phase of the hard magnetic phase in the nano composite permanent magnetic material of the comparative example 1 is Sm2Co17Phase (instead of SmCo)5Phase), and the main phase of the hard magnetic phase in the nanocomposite permanent magnetic material of example 1 and example 3 is SmCo5The test results were in agreement with those in test example 2.

Claims (9)

1. High-coercivity SmCo5the/FeCo nano composite permanent magnetic material is characterized by comprising SmCo5α -Fe and SmCo5Mixing hard magnetic phase stabilizing components, compacting, and thermally deforming to obtain SmCo5The hard magnetic phase stabilizing component is SmNi alloy and/or SmZn alloy, and the α -Fe is SmCo5And α -Fe accounting for 20-50% of the total mass.
2. High coercivity SmCo according to claim 15the/FeCo nano composite permanent magnetic material is characterized in that the SmCo nano composite permanent magnetic material5The hard magnetic phase stabilizing component has a mass of SmCo5α -Fe and SmCo52.5-10% of the total mass of the hard magnetic phase stabilizing components, 50-90% of Sm in the SmNi and SmZn alloy, and the balance of Ni or Zn.
3. A high coercive force SmCo as claimed in claim 1 or 25The preparation method of the/FeCo nano composite permanent magnetic material is characterized by comprising the following steps of: SmCo is mixed5α -Fe and SmCo5Uniformly mixing the hard magnetic phase stabilizing components to obtain a mixture; and (3) pressing and forming the mixture, and then carrying out thermal deformation treatment.
4. High coercivity SmCo according to claim 35The preparation method of the/FeCo nano composite permanent magnetic material is characterized in that the temperature during thermal deformation treatment is 600-900 ℃, the deformation amount is 30-90%, and the deformation rate is 5% -100%/min.
5. High coercivity SmCo according to claim 35The preparation method of the/FeCo nano composite permanent magnetic material is characterized in that the SmCo nano composite permanent magnetic material is prepared by the method5The hard magnetic phase stabilizing component is an alloy rapid-hardening thin strip, and the thickness of the alloy rapid-hardening thin strip is 10-200 mu m.
6. The high coercive force SmCo as claimed in any one of claims 3 to 55The preparation method of the/FeCo nano composite permanent magnetic material is characterized in that the SmCo nano composite permanent magnetic material is prepared by the method5α -Fe is powder with particle size less than 180 μm.
7. The high coercive force SmCo as claimed in any one of claims 3 to 55The preparation method of the/FeCo nano composite permanent magnetic material is characterized in that the mixing is ball milling mixing, the ball milling time is 4-24 hours, and the rotating speed is 300-700 r/min.
8. The high coercive force SmCo as claimed in any one of claims 3 to 55The preparation method of the/FeCo nano composite permanent magnetic material is characterized in that the pressure used in the compression molding is 0.8-1.2 GPa.
9. The high coercive force SmCo as claimed in any one of claims 3 to 55The preparation method of the/FeCo nano composite permanent magnetic material is characterized in that the mixing, the compression molding and the thermal deformation treatment are all carried out in a protective atmosphere.
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Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20020084439A1 (en) * 2000-12-28 2002-07-04 Xerox Corporation Extrudable magnet compound with improved flow properties
US20150104645A1 (en) * 2010-07-21 2015-04-16 Alexandr Gabay Magnetic nanoflakes
CN108220732A (en) * 2016-12-22 2018-06-29 有研稀土新材料股份有限公司 The method of modifying of alloy material, bonded permanent magnet and rare earth permanent magnet powder
US20180277289A1 (en) * 2017-03-21 2018-09-27 Intermolecular, Inc. Inverse Phase Allotrope Rare Earth Magnets
CN108962523A (en) * 2018-08-14 2018-12-07 徐靖才 A kind of preparation method for the SmCo base nanocomposite permanent magnets adulterating SmCu alloy

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20020084439A1 (en) * 2000-12-28 2002-07-04 Xerox Corporation Extrudable magnet compound with improved flow properties
US20150104645A1 (en) * 2010-07-21 2015-04-16 Alexandr Gabay Magnetic nanoflakes
CN108220732A (en) * 2016-12-22 2018-06-29 有研稀土新材料股份有限公司 The method of modifying of alloy material, bonded permanent magnet and rare earth permanent magnet powder
US20180277289A1 (en) * 2017-03-21 2018-09-27 Intermolecular, Inc. Inverse Phase Allotrope Rare Earth Magnets
CN108962523A (en) * 2018-08-14 2018-12-07 徐靖才 A kind of preparation method for the SmCo base nanocomposite permanent magnets adulterating SmCu alloy

Non-Patent Citations (2)

* Cited by examiner, † Cited by third party
Title
CHUANBING RONG等: "Fabrication of bulk nanocomposite magnets via severe plastic deformation and warm compaction", 《APPLIED PHYSICS LETTERS》 *
陈静武等: "Fe纳米颗粒掺杂制备各向异性SmCo5/Fe纳米双相复合磁体的结构与磁性研究", 《科技企业家》 *

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