WO2021169903A1 - Rare earth permanent magnet material, preparation method therefor, and application thereof - Google Patents

Rare earth permanent magnet material, preparation method therefor, and application thereof Download PDF

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WO2021169903A1
WO2021169903A1 PCT/CN2021/077195 CN2021077195W WO2021169903A1 WO 2021169903 A1 WO2021169903 A1 WO 2021169903A1 CN 2021077195 W CN2021077195 W CN 2021077195W WO 2021169903 A1 WO2021169903 A1 WO 2021169903A1
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content
permanent magnet
weight percentage
rtb
magnet material
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PCT/CN2021/077195
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French (fr)
Chinese (zh)
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付刚
黄佳莹
黄清芳
黄吉祥
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厦门钨业股份有限公司
福建省长汀金龙稀土有限公司
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Publication of WO2021169903A1 publication Critical patent/WO2021169903A1/en

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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F1/00Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
    • H01F1/01Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials
    • 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
    • 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
    • H01F1/057Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B
    • H01F1/0571Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B in the form of particles, e.g. rapid quenched powders or ribbon flakes
    • H01F1/0575Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B in the form of particles, e.g. rapid quenched powders or ribbon flakes pressed, sintered or bonded together
    • H01F1/0577Alloys characterised by their composition containing rare earth metals and magnetic transition metals, e.g. SmCo5 and IIIa elements, e.g. Nd2Fe14B in the form of particles, e.g. rapid quenched powders or ribbon flakes pressed, sintered or bonded together sintered
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F41/00Apparatus 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
    • 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
    • H01F41/0266Moulding; Pressing

Definitions

  • the invention relates to a rare earth permanent magnet material and a preparation method and application thereof.
  • RTB series sintered magnets (R refers to rare earth elements, T refers to transition metal elements and metal elements of the third main group, B refers to boron element) is currently the most used rare earth permanent magnet material, which is widely used in electronics, electrical machinery, and medical equipment. , Toys, packaging, hardware machinery, aerospace and other fields, the more common ones are permanent magnet motors, speakers, magnetic separators, computer disk drives, magnetic resonance imaging equipment and meters.
  • heavy rare earth elements such as Dy, Tb, Gd, etc. are generally added to increase the coercivity of materials and improve the temperature coefficient.
  • the price of heavy rare earths is high. This method is used to increase the coercivity of RTB-based sintered magnet products. Force, will increase the cost of raw materials, is not conducive to the application of RTB series sintered magnets.
  • the technical problem to be solved by the present invention is to overcome the defects of degraded magnet performance and poor consistency when the B of the R-T-B system magnet in the R-T-B magnet is less than 5.88 at% in the prior art, and provides a rare earth permanent magnet material and a preparation method and application thereof.
  • the rare earth permanent magnetic material of the invention has high coercivity Hcj and Br, good temperature stability of the magnet, and excellent performance; and the demagnetization curve has no steps, the relative permeability is low, and the magnetic steel has good uniformity.
  • the present invention solves the above technical problems through the following technical solutions.
  • the present invention provides a R-T-B series permanent magnetic material, which contains: R, Ga, Al, Fe and B, and also contains one or more of Ti, Zr and Nb, and its content is as follows in weight percentage:
  • R is 28.5-33.05%; said R is a rare earth element containing at least Nd;
  • the content of Ga is greater than 0.35%
  • the content of B is 0.84 ⁇ 0.945%
  • the content of Al is less than 0.08%
  • the content of Ti is 0.145-0.255%
  • the content of the Zr is 0.185-0.355 %
  • the content of Nb is 0.195 to 0.505%
  • the R-T-B-based permanent magnet material does not contain Co.
  • the content of R is preferably 28.5% to 33.015% by weight percentage, such as 28.5%, 28.504%, 28.508%, 28.509%, 28.708%, 29.187%, 29.6%, 29.703%, 29.904% , 29.992%, 30.097%, 30.196%, 30.401%, 30.61%, 31.013%, 31.504%, 31.696%, 31.704%, 31.806%, 31.998%, 32.21% or 33.015%.
  • the Nd content is preferably 9.602% to 32.907% by weight percentage, such as 9.602%, 10.983%, 11.506%, 14.605%, 14.98%, 28.205%, 28.297%, 28.495%, 28.504% , 28.509%, 29.404%, 29.595%, 29.703%, 29.904%, 30.196%, 30.204%, 30.205%, 31.013%, 31.504%, 31.508%, 31.806%, 32.012% or 32.907%.
  • the R preferably contains Pr.
  • the content of Pr is preferably less than 0.5%, or greater than 17%, such as 0.108%, 0.196%, 0.197%, 0.198%, 0.203%, 0.205%, 0.303%, 0.394%, 0.397%, 0.405%, 17.018%, 17.605%, 18.197%, 18.204% or 19.106%.
  • the R preferably contains a heavy rare earth element RH.
  • the RH is preferably one or more of Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu and Y.
  • the content of the RH is preferably 1.5-6.0%, for example, 2.987% or 3.012%.
  • the Ga content is preferably 0.35% ⁇ Ga ⁇ 0.55%, or 0.55wt% ⁇ Ga ⁇ 1.05wt%, or 1.05wt% ⁇ Ga ⁇ 1.25wt%, or Ga ⁇ 1.25wt%, such as 0.398%, 0.552%, 0.602%, 0.703%, 0.704%, 0.791%, 0.802%, 0.804%, 0.987%, 1.052%, 1.053%, 1.101%, 1.103%, 1.203%, 1.253% , 1.303%, 1.304%, 1.505% or 1.789%.
  • the content of B is preferably 0.915% to 0.94% in terms of weight percentage.
  • the content of B is preferably 0.844%, 0.845%, 0.863%, 0.883%, 0.893%, 0.901%, 0.904%, 0.922%, 0.923%, 0.924%, 0.925%, 0.942% or 0.943%.
  • the content of B is preferably greater than or equal to 0.915 wt% and 5.55 at%; wherein, the wt% is a weight percentage, and the at% is an atomic percentage.
  • the content of Al is less than 0.08% by weight percentage. It should be noted that this content of Al is generally not added actively, specifically due to the very small amount of impurities in the equipment and/or raw materials used in the preparation process, the Al content is less than 0.08%.
  • the content of Al is preferably 0.03% ⁇ Al ⁇ 0.05%, or the content of Al is less than 0.03%, such as 0.031%, 0.032%, 0.033%, 0.038%, 0.039% , 0.041%, 0.042%, 0.048% or 0.049%.
  • the content of Ti is preferably 0.149% to 0.254%, for example, 0.149%, 0.152%, 0.153%, 0.154%, 0.156 in terms of weight percentage. %, 0.204%, 0.205% or 0.254%.
  • the content of Zr is preferably 0.2% ⁇ Zr ⁇ (3.48B-2.67)%, for example, 0.26% ⁇ Zr ⁇ (3.48 B-2.67)%.
  • the content of Zr is preferably 0.189% to 0.353%, for example, 0.189%, 0.198%, 0.252%, 0.262%, 0.263% by weight. %, 0.291%, 0.297%, 0.301%, 0.303%, 0.329%, 0.348%, 0.352% or 0.353%.
  • the content of Nb is preferably 0.198% to 0.505%, such as 0.198%, 0.201%, 0.202%, 0.204%, 0.205, in terms of weight percentage. %, 0.206%, 0.304%, 0.404% or 0.505%.
  • the Nb content or the Ti content is 0.55% or more in atomic percentage.
  • the R-T-B-based permanent magnetic material does not contain Cu.
  • the Fe content is the balance in terms of weight percentage. More preferably, in terms of weight percentage, the content of Fe is 64.5% to 69.6%, such as 64.707%, 65.367%, 65.392%, 65.473%, 65.568%, 65.837%, 66.01%, 66.187%, 66.198%, 66.199%, 66.557%, 66.782%, 67.114%, 67.468%, 67.621%, 67.797%, 68.118%, 68.637%, 68.792%, 68.794%, 69.21%, 69.258%, 69.486%, or 69.573%.
  • the RTB-based permanent magnetic material includes a R 2 Fe 14 B main phase, a grain boundary phase, and a rare earth-rich phase.
  • the grain boundary phase refers to the general term of the grain boundary phase between two or more R 2 Fe 14 B crystal grains.
  • the grain boundary phase preferably includes R 6 Fe 13 Ga.
  • the volume fraction of R 6 Fe 13 Ga is preferably 2.5 to 10.8%, for example 2.5%, 3.2%, 3.4%, 4.6%, 4.8%, 5.7%, 6.3%, 6.4%, 6.5%, 6.7% %, 7.2%, 7.3%, 7.6%, 7.7%, 7.8%, 7.9%, 8.4%, 8.5%, 8.8%, 10.5% or 10.8%; wherein the percentage refers to the R 6 Fe 13 Ga
  • the volume accounts for the percentage of the total volume of the grain boundary phase, the R 2 Fe 14 B main phase, and the rare earth-rich phase.
  • the present invention also provides a method for preparing the RTB-based permanent magnet material as described above, and the steps include: sequentially smelting, casting, hydrogen breaking, jet milling, forming, sintering and aging of the raw materials of the RTB-based permanent magnet material. , You can.
  • the raw material of the R-T-B-based permanent magnetic material is known to those skilled in the art as the raw material that satisfies the element content of the R-T-B-based permanent magnetic material as described above.
  • the operation and conditions of the smelting can be conventional in the art.
  • the raw materials are smelted in a high-frequency vacuum melting furnace.
  • the vacuum degree of the smelting furnace is less than 0.1 Pa, more preferably less than 0.02 Pa.
  • the melting temperature is 1450-1550°C, more preferably 1500-1550°C.
  • the operation and conditions of the casting can be conventional in the art, and are generally carried out in an inert atmosphere to obtain an alloy cast piece of RTB-based permanent magnet material.
  • an Ar atmosphere e.g. under Ar atmosphere of 5.5 ⁇ 10 4 Pa
  • the cooling can be achieved by passing cooling water into the copper roller.
  • the water inlet temperature of the copper roller is ⁇ 25°C, for example, 23.1°C, 23.3°C, 23.4°C, 23.5°C, 23.6°C, 23.7°C, 23.8°C or 24.2°C.
  • the operation and conditions of the hydrogen breaker can be conventional in the art.
  • the hydrogen destruction includes a hydrogen adsorption process and a dehydrogenation process, and the R-T-B series permanent magnet material alloy cast piece can be subjected to hydrogen destruction treatment to obtain R-T-B series permanent magnet material alloy powder.
  • the hydrogen absorption temperature of the hydrogen breaker is 20 to 300°C, for example, 25°C.
  • the hydrogen absorption pressure of the hydrogen breaker is 0.12 to 0.19 MPa, for example, 0.19 MPa.
  • the dehydrogenation time of the hydrogen breaking is 0.5-5h, for example 2h.
  • the dehydrogenation temperature of the hydrogen breakdown is 450-600°C, for example, 550°C.
  • the operation and conditions of the jet mill can be conventional in the art.
  • the jet mill is to send the R-T-B series permanent magnet material alloy powder to the jet mill for jet milling to continue to be crushed to obtain the R-T-B series permanent magnet material fine powder.
  • the oxygen content in the grinding chamber of the jet mill in the jet mill is below 120 ppm.
  • the rotation speed of the sorting wheel in the jet mill is 3500-4300 rpm/min, preferably 3900-4100 rpm/min, for example 4000 rpm/min.
  • the grinding pressure of the jet mill is 0.3-0.5 MPa, for example 0.4 MPa.
  • the median particle size D50 of the fine powder of the R-T-B permanent magnetic material is 3 to 5.5 ⁇ m, for example, 4 ⁇ m.
  • the molding operation and conditions can be conventional in the art.
  • the molding is performed at a magnetic field strength above 1.8T, such as 1.8T, and under the protection of a nitrogen atmosphere.
  • the sintering operation and conditions can be conventional in the art.
  • the sintering temperature is 900 to 1300°C, more preferably 1000 to 1100°C, such as 1050°C, 1055°C, 1065°C, 1070°C, 1075°C, 1080°C, 1085°C, 1087°C, 1088°C or 1090°C.
  • the sintering time is 5-10h, for example 8h.
  • the aging operation and conditions can be conventional in the art.
  • the aging includes primary aging and secondary aging.
  • the temperature of the primary aging is 850°C to 950°C, for example, 900°C.
  • the secondary aging temperature is 430°C to 560°C, preferably 460 to 490°C, for example, 460°C, 470°C, 475°C, 477°C or 480°C.
  • the time of the primary aging treatment is 2 to 5 hours, for example, 3 hours.
  • the time of the secondary aging treatment is 2 to 5 hours, for example, 3 hours.
  • the invention also provides an application of the aforementioned R-T-B series permanent magnet material in automobile rotors, automobile drive motors, wind power or water pumps.
  • the reagents and raw materials used in the present invention are all commercially available.
  • the formula of the R-T-B permanent magnet material is designed to be low in B content, high in Ga content, free of Al (a very small amount of impurities in the equipment and/or raw materials used in the preparation process) and free of Co.
  • the coercivity Hcj ( ⁇ 16.61kOe) and Br ( ⁇ 11.73kGs) of the RTB-based permanent magnet material are high. After adding heavy rare earth elements, Hcj can reach more than 29.24kOe, and the temperature stability of the magnet is good. Excellent performance; and its demagnetization curve has no steps, the relative permeability is low, the coercive force is less than 1.5kOe in the same batch, and the magnetic steel has good uniformity (squareness ⁇ 97%).
  • the dehydrogenation time of hydrogen breakdown is 2h.
  • the dehydrogenation temperature is 550°C to obtain R-T-B alloy powder.
  • Jet mill The R-T-B alloy powder is sent to the jet mill for jet milling to continue to be crushed to obtain R-T-B fine powder.
  • the oxygen content in the grinding chamber of the jet mill in the jet mill is below 120 ppm.
  • the speed of the sorting wheel in the jet mill is 4000 rpm/min.
  • the grinding pressure of the jet mill is 0.4MPa.
  • the median particle diameter D50 of the obtained R-T-B fine powder was 4 ⁇ m.
  • the molding is carried out under the protection of 1.8T magnetic field strength and nitrogen atmosphere.
  • the sintering time is 8h.
  • the temperature of primary aging is 900°C; the temperature of secondary aging (as shown in Table 2) is 470°C.
  • the treatment time of primary aging is 3h, and the treatment time of secondary aging is 3h.
  • the raw materials were prepared according to the formula shown in Table 1, and except for the conditions shown in Table 2, the other process conditions were the same as those in Example 1, and the R-T-B series permanent magnet material was prepared.
  • Example 1 Number/wt% Cooling water temperature during casting Sintering temperature Secondary aging temperature
  • Example 2 23.3 1080
  • Example 3 23.1 1065 477
  • Example 4 24.2 1070 475
  • Example 5 23.6
  • 1090 480 Example 6 23.8 1090 470
  • Example 7 23.8 1087 460
  • Example 8 23.4 1085 480
  • Example 9 23.7 1088 477
  • Example 10 23.8 1090 475
  • Example 11 23.6 1055
  • Example 12 23.3 1085 470
  • Example 13 23.1 1085 460
  • Example 14 24.2 1070 480
  • Example 15 23.6 1065 477
  • Example 16 23.8 1070 475
  • Example 17 23.8 1085 480
  • Example 18 23.4 1075 470
  • Example 19 23.7 1085 460
  • Example 20 23.3 1070 480
  • Example 21 23.1 1065 477
  • Example 22 24.2 1070 475
  • Example 23 23.6 1050
  • Example 24 23.8 1050 470 Comparative example 1 23.8 1070 490
  • Comparative example 2 Comparative example 23.4 1080 500 Comparative example 3 23.7 1085 510 Comparative example 4 23.8 1065 500 Comparative example 5 23.6 1035 490
  • Comparative example 6 23.7 1095 490
  • Comparative example 7 23.8 1070 495 Comparative example
  • the content of Al in the sintered magnet in Table 3 is the sum of the content of Al in the raw material and the content of Al introduced in other raw materials and processes (for example, a crucible made of alumina during smelting).
  • Magnetic performance evaluation The samples of Examples 1-24 and Comparative Examples 1-8 were tested for magnetic performance using the NIM-10000H BH bulk rare earth permanent magnet non-destructive measurement system of China Metrology Institute.
  • the magnetic performance test sample size is a cylinder of 10mm*10mm.
  • the following table shows the magnetic performance test results.
  • the 6-13-1 phase in Table 4 refers to the RE 6 Fe 13 Ga phase, in which: the volume ratio of the 6-13-1 phase to the overall phase refers to the RE 6 Fe 13 Ga phase in the overall phase By volume ratio, the overall phase includes grain boundary phase, R 2 Fe 14 B main phase and rare earth-rich phase.
  • the magnetic properties of the RTB-based permanent magnet materials in Comparative Examples 1 to 8 are the best properties that can be obtained after the formulations of Comparative Examples 1 to 8 are optimized by process (water inlet temperature, sintering temperature, aging temperature).
  • FE-EPMA is used to detect
  • the vertical orientation surface of R-T-B series permanent magnetic material is polished
  • the field emission electron probe microanalyzer (FE-EPMA) (JEOL, 8530F) is used to detect.
  • FE-EPMA field emission electron probe microanalyzer
  • Br or Hcj refer to the average value: the average value calculated by testing the remanence or coercivity of 5 rare earth permanent magnetic material samples (cylinder 10mm*10mm) in the same batch.
  • the volume ratio and temperature coefficient of the 6-13-1 phase in the overall phase are also taken after measuring the average value of the performance of 5 rare earth permanent magnetic material samples (cylinder 10mm*10mm) in the same batch. value.
  • each embodiment and comparative example of the present invention several magnets are prepared, and the same batch refers to the sample obtained by cutting the magnet material obtained in each embodiment and comparative example according to the unit of the performance test.
  • the relative permeability is Br/Hcb; among them, Br is the remanence and Hcb is the magnetic coercivity.
  • Br is the remanence
  • Hcb is the magnetic coercivity.
  • Max(Hcj)-Min(Hcj) The maximum value of the coercive force minus the minimum value of the coercive force in the same batch of products. If it is greater than 1.5kOe, the magnetic performance consistency is poor.

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  • Power Engineering (AREA)
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Abstract

A rare earth permanent magnet material, a preparation method therefor, and an application thereof. The rare earth permanent magnet material contains: R, Ga, Al, Fe, and B, also contains one or more of Ti, Zr, and Nb, and contains the following according to weight percentage: the content of R is 28.5-33.05%, the content of Ga is greater than 0.35%, the content of B is 0.84-0.945%, the content of Al is less than 0.08%, and an R-T-B permanent magnet material does not contain Co. The rare earth permanent magnet material has high coercivity Hcj and Br, a stable magnet temperature, and an excellent performance. In addition, the demagnetization curve thereof is step-less, the relative magnetic permeability is low, and the magnetic steel uniformity is good.

Description

一种稀土永磁材料及其制备方法和应用Rare earth permanent magnet material and preparation method and application thereof 技术领域Technical field
本发明涉及一种稀土永磁材料及其制备方法和应用。The invention relates to a rare earth permanent magnet material and a preparation method and application thereof.
背景技术Background technique
R-T-B系烧结磁铁(R指稀土元素,T指过渡金属元素及第三主族金属元素,B指硼元素)是目前使用量最大的稀土永磁材料,被广泛应用于电子、电力机械、医疗器械、玩具、包装、五金机械、航天航空等领域,较常见的有永磁电机、扬声器、磁选机、计算机磁盘驱动器、磁共振成像设备仪表等。RTB series sintered magnets (R refers to rare earth elements, T refers to transition metal elements and metal elements of the third main group, B refers to boron element) is currently the most used rare earth permanent magnet material, which is widely used in electronics, electrical machinery, and medical equipment. , Toys, packaging, hardware machinery, aerospace and other fields, the more common ones are permanent magnet motors, speakers, magnetic separators, computer disk drives, magnetic resonance imaging equipment and meters.
实验中发现,在B含量较高的情况下,会生成较多的富B相,进而影响到产品的剩磁性能。因此,为了提升R-T-B系烧结磁铁的剩磁,通常需要降低B含量,但是当B含量低于5.88at%时,由Nd-Fe-B三元相图可知易形成R 2T 17相,而R 2T 17不具有室温单轴各向异性,进而使得磁体的性能劣化。 It is found in the experiment that when the B content is high, more B-rich phases will be generated, which will affect the remanence performance of the product. Therefore, in order to increase the remanence of RTB-based sintered magnets, it is usually necessary to reduce the B content. However, when the B content is less than 5.88 at%, the Nd-Fe-B ternary phase diagram shows that the R 2 T 17 phase is easily formed, and the R 2 T 17 does not have uniaxial anisotropy at room temperature, which in turn degrades the performance of the magnet.
现有技术中,一般通过添加重稀土元素例如Dy、Tb、Gd等,以提高材料的矫顽力以及改善温度系数,但重稀土价格高昂,采用这种方法提高R-T-B系烧结磁体产品的矫顽力,会增加原材料成本,不利于R-T-B系烧结磁体的应用。In the prior art, heavy rare earth elements such as Dy, Tb, Gd, etc. are generally added to increase the coercivity of materials and improve the temperature coefficient. However, the price of heavy rare earths is high. This method is used to increase the coercivity of RTB-based sintered magnet products. Force, will increase the cost of raw materials, is not conducive to the application of RTB series sintered magnets.
因此,在不添加或少量添加重稀土的情况下,如何采用低B体系(B<5.88at%)制备得到高矫顽力、高剩磁的R-T-B系磁铁是本领域亟待解决的技术问题。Therefore, how to prepare R-T-B magnets with high coercivity and high remanence by using a low-B system (B<5.88at%) without adding or adding a small amount of heavy rare earth is a technical problem to be solved urgently in this field.
发明内容Summary of the invention
本发明所要解决的技术问题在于克服现有技术中当R-T-B系磁体中B<5.88at%时,磁体性能劣化且一致性差的缺陷,而提供了一种稀土永磁材料及其制备方法和应用。本发明稀土永磁材料矫顽力Hcj和Br高,磁体温度稳定性好,性能优异;且其退磁曲线无台阶,相对磁导率低,磁钢均一性好。The technical problem to be solved by the present invention is to overcome the defects of degraded magnet performance and poor consistency when the B of the R-T-B system magnet in the R-T-B magnet is less than 5.88 at% in the prior art, and provides a rare earth permanent magnet material and a preparation method and application thereof. The rare earth permanent magnetic material of the invention has high coercivity Hcj and Br, good temperature stability of the magnet, and excellent performance; and the demagnetization curve has no steps, the relative permeability is low, and the magnetic steel has good uniformity.
本发明通过以下技术方案解决上述技术问题。The present invention solves the above technical problems through the following technical solutions.
本发明提供了一种R-T-B系永磁材料,其包含:R、Ga、Al、Fe和B,还包含Ti、Zr和Nb的一种或多种,以重量百分比计,其含量如下:The present invention provides a R-T-B series permanent magnetic material, which contains: R, Ga, Al, Fe and B, and also contains one or more of Ti, Zr and Nb, and its content is as follows in weight percentage:
R的含量为28.5~33.05%;所述R为至少含有Nd的稀土元素;The content of R is 28.5-33.05%; said R is a rare earth element containing at least Nd;
Ga的含量大于0.35%;The content of Ga is greater than 0.35%;
B的含量为0.84~0.945%;The content of B is 0.84~0.945%;
Al的含量小于0.08%;The content of Al is less than 0.08%;
当所述R-T-B系永磁材料包含Ti时,所述Ti的含量为0.145~0.255%;When the R-T-B series permanent magnetic material contains Ti, the content of Ti is 0.145-0.255%;
当所述R-T-B系永磁材料包含Zr时,所述Zr的含量为0.185~0.355%;When the R-T-B series permanent magnetic material contains Zr, the content of the Zr is 0.185-0.355 %;
当所述R-T-B系永磁材料包含Nb时,所述Nb的含量为0.195~0.505%;When the R-T-B series permanent magnet material contains Nb, the content of Nb is 0.195 to 0.505%;
所述R-T-B系永磁材料中不含有Co。The R-T-B-based permanent magnet material does not contain Co.
本发明中,以重量百分比计,所述R的含量优选地为28.5~33.015%,例如为28.5%、28.504%、28.508%、28.509%、28.708%、29.187%、29.6%、29.703%、29.904%、29.992%、30.097%、30.196%、30.401%、30.61%、31.013%、31.504%、31.696%、31.704%、31.806%、31.998%、32.21%或33.015%。In the present invention, the content of R is preferably 28.5% to 33.015% by weight percentage, such as 28.5%, 28.504%, 28.508%, 28.509%, 28.708%, 29.187%, 29.6%, 29.703%, 29.904% , 29.992%, 30.097%, 30.196%, 30.401%, 30.61%, 31.013%, 31.504%, 31.696%, 31.704%, 31.806%, 31.998%, 32.21% or 33.015%.
本发明中,以重量百分比计,所述Nd的含量优选地为9.602~32.907%,例如为9.602%、10.983%、11.506%、14.605%、14.98%、28.205%、28.297%、28.495%、28.504%、28.509%、29.404%、29.595%、29.703%、29.904%、30.196%、30.204%、30.205%、31.013%、31.504%、31.508%、31.806%、32.012%或32.907%。In the present invention, the Nd content is preferably 9.602% to 32.907% by weight percentage, such as 9.602%, 10.983%, 11.506%, 14.605%, 14.98%, 28.205%, 28.297%, 28.495%, 28.504% , 28.509%, 29.404%, 29.595%, 29.703%, 29.904%, 30.196%, 30.204%, 30.205%, 31.013%, 31.504%, 31.508%, 31.806%, 32.012% or 32.907%.
本发明中,所述R中优选地包含Pr。In the present invention, the R preferably contains Pr.
其中,以重量百分比计,所述Pr的含量优选地为小于0.5%,或者大于17%,例如为0.108%、0.196%、0.197%、0.198%、0.203%、0.205%、0.303%、0.394%、0.397%、0.405%、17.018%、17.605%、18.197%、18.204%或19.106%。Wherein, in terms of weight percentage, the content of Pr is preferably less than 0.5%, or greater than 17%, such as 0.108%, 0.196%, 0.197%, 0.198%, 0.203%, 0.205%, 0.303%, 0.394%, 0.397%, 0.405%, 17.018%, 17.605%, 18.197%, 18.204% or 19.106%.
本发明中,所述R中优选地包含重稀土元素RH。In the present invention, the R preferably contains a heavy rare earth element RH.
其中,所述RH优选地为Gd、Tb、Dy、Ho、Er、Tm、Yb、Lu和Y的一种或多种。Wherein, the RH is preferably one or more of Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu and Y.
其中,以重量百分比计,所述RH的含量优选地为1.5~6.0%,例如为2.987%或3.012%。Wherein, in terms of weight percentage, the content of the RH is preferably 1.5-6.0%, for example, 2.987% or 3.012%.
本发明中,以重量百分比计,所述Ga的含量优选地为0.35%<Ga<0.55%,或者0.55wt%≤Ga<1.05wt%,或者1.05wt%≤Ga<1.25wt%,或者Ga≥1.25wt%,例如为0.398%、0.552%、0.602%、0.703%、0.704%、0.791%、0.802%、0.804%、0.987%、1.052%、1.053%、1.101%、1.103%、1.203%、1.253%、1.303%、1.304%、1.505%或1.789%。In the present invention, in terms of weight percentage, the Ga content is preferably 0.35%<Ga<0.55%, or 0.55wt%≤Ga<1.05wt%, or 1.05wt%≤Ga<1.25wt%, or Ga≥ 1.25wt%, such as 0.398%, 0.552%, 0.602%, 0.703%, 0.704%, 0.791%, 0.802%, 0.804%, 0.987%, 1.052%, 1.053%, 1.101%, 1.103%, 1.203%, 1.253% , 1.303%, 1.304%, 1.505% or 1.789%.
本发明中,以重量百分比计,所述B的含量优选地为0.915%~0.94%。In the present invention, the content of B is preferably 0.915% to 0.94% in terms of weight percentage.
本发明中,以重量百分比计,所述B的含量优选地为0.844%、0.845%、0.863%、0.883%、0.893%、0.901%、0.904%、0.922%、0.923%、0.924%、0.925%、0.942%或0.943%。In the present invention, in terms of weight percentage, the content of B is preferably 0.844%, 0.845%, 0.863%, 0.883%, 0.893%, 0.901%, 0.904%, 0.922%, 0.923%, 0.924%, 0.925%, 0.942% or 0.943%.
本发明中,所述B的含量优选地≥0.915wt%和5.55at%中的大者;其中,所述wt%为重量百分比,所述at%为原子百分比。In the present invention, the content of B is preferably greater than or equal to 0.915 wt% and 5.55 at%; wherein, the wt% is a weight percentage, and the at% is an atomic percentage.
本发明中,以重量百分比计,所述Al的含量<0.08%。需要说明的是,该含量的Al一般不是主动添加,具体由于制备过程中使用的设备和/或原材料中极少量的杂质,使得Al的含量<0.08%。In the present invention, the content of Al is less than 0.08% by weight percentage. It should be noted that this content of Al is generally not added actively, specifically due to the very small amount of impurities in the equipment and/or raw materials used in the preparation process, the Al content is less than 0.08%.
其中,以重量百分比计,所述Al的含量优选地为0.03%≤Al<0.05%,或者,所述Al的含量小于0.03%,例如为0.031%、0.032%、0.033%、0.038%、0.039%、0.041%、0.042%、0.048%或0.049%。Wherein, in terms of weight percentage, the content of Al is preferably 0.03%≤Al<0.05%, or the content of Al is less than 0.03%, such as 0.031%, 0.032%, 0.033%, 0.038%, 0.039% , 0.041%, 0.042%, 0.048% or 0.049%.
本发明中,以原子百分比计,优选地,当所述R中包含Pr时,B/(Pr+Nd)≥0.405。In the present invention, in terms of atomic percentage, preferably, when Pr is contained in the R, B/(Pr+Nd)≥0.405.
本发明中,以原子百分比计,优选地,Ga>7.2941-1.24B。In the present invention, in terms of atomic percentage, preferably, Ga>7.2941-1.24B.
本发明中,以原子百分比计,优选地,B/R≥0.38。In the present invention, in terms of atomic percentage, preferably, B/R≥0.38.
本发明中,当所述R-T-B系永磁材料包含Ti时,以重量百分比计,所述Ti的含量优选地为0.149%~0.254%,例如为0.149%、0.152%、0.153%、0.154%、0.156%、0.204%、0.205%或0.254%。In the present invention, when the RTB-based permanent magnetic material contains Ti, the content of Ti is preferably 0.149% to 0.254%, for example, 0.149%, 0.152%, 0.153%, 0.154%, 0.156 in terms of weight percentage. %, 0.204%, 0.205% or 0.254%.
本发明中,当所述R-T-B系永磁材料包含Zr时,以重量百分比计,所 述Zr的含量优选地为0.2%≤Zr<(3.48B-2.67)%,例如0.26%≤Zr<(3.48B-2.67)%。In the present invention, when the RTB-based permanent magnetic material contains Zr, the content of Zr is preferably 0.2%≤Zr<(3.48B-2.67)%, for example, 0.26%≤Zr<(3.48 B-2.67)%.
本发明中,当所述R-T-B系永磁材料包含Zr时,以重量百分比计,所述Zr的含量优选地为0.189%~0.353%,例如为0.189%、0.198%、0.252%、0.262%、0.263%、0.291%、0.297%、0.301%、0.303%、0.329%、0.348%、0.352%或0.353%。In the present invention, when the RTB-based permanent magnetic material contains Zr, the content of Zr is preferably 0.189% to 0.353%, for example, 0.189%, 0.198%, 0.252%, 0.262%, 0.263% by weight. %, 0.291%, 0.297%, 0.301%, 0.303%, 0.329%, 0.348%, 0.352% or 0.353%.
本发明中,当所述R-T-B系永磁材料包含Nb时,以重量百分比计,所述Nb的含量优选地为0.198%~0.505%,例如为0.198%、0.201%、0.202%、0.204%、0.205%、0.206%、0.304%、0.404%或0.505%。In the present invention, when the RTB-based permanent magnetic material contains Nb, the content of Nb is preferably 0.198% to 0.505%, such as 0.198%, 0.201%, 0.202%, 0.204%, 0.205, in terms of weight percentage. %, 0.206%, 0.304%, 0.404% or 0.505%.
本发明中,当所述R-T-B系永磁材料包含Nb或Ti时,以原子百分比计,所述Nb的含量或所述Ti的含量为0.55%以上。In the present invention, when the R-T-B-based permanent magnetic material contains Nb or Ti, the Nb content or the Ti content is 0.55% or more in atomic percentage.
本发明中,优选地,所述R-T-B系永磁材料中不含有Cu。In the present invention, preferably, the R-T-B-based permanent magnetic material does not contain Cu.
本发明中,优选地,以重量百分比计,所述Fe的含量为余量。更优选地,以重量百分比计,所述Fe的含量为64.5%~69.6%,例如为64.707%、65.367%、65.392%、65.473%、65.568%、65.837%、66.01%、66.187%、66.198%、66.199%、66.557%、66.782%、67.114%、67.468%、67.621%、67.797%、68.118%、68.637%、68.792%、68.794%、69.21%、69.258%、69.486%或69.573%。In the present invention, preferably, the Fe content is the balance in terms of weight percentage. More preferably, in terms of weight percentage, the content of Fe is 64.5% to 69.6%, such as 64.707%, 65.367%, 65.392%, 65.473%, 65.568%, 65.837%, 66.01%, 66.187%, 66.198%, 66.199%, 66.557%, 66.782%, 67.114%, 67.468%, 67.621%, 67.797%, 68.118%, 68.637%, 68.792%, 68.794%, 69.21%, 69.258%, 69.486%, or 69.573%.
本发明中,优选地,所述R-T-B系永磁材料包含R 2Fe 14B主相、晶界相和富稀土相。 In the present invention, preferably, the RTB-based permanent magnetic material includes a R 2 Fe 14 B main phase, a grain boundary phase, and a rare earth-rich phase.
其中,所述晶界相指的是两个或两个以上的R 2Fe l4B晶粒间的晶界相的总称。 Wherein, the grain boundary phase refers to the general term of the grain boundary phase between two or more R 2 Fe 14 B crystal grains.
其中,所述晶界相优选地包含R 6Fe 13Ga。 Wherein, the grain boundary phase preferably includes R 6 Fe 13 Ga.
其中,所述R 6Fe 13Ga的体积分数优选地为2.5~10.8%,例如为2.5%、3.2%、3.4%、4.6%、4.8%、5.7%、6.3%、6.4%、6.5%、6.7%、7.2%、7.3%、7.6%、7.7%、7.8%、7.9%、8.4%、8.5%、8.8%、10.5%或10.8%;其中,所述百分比是指所述R 6Fe 13Ga的体积在所述晶界相、所述R 2Fe 14B主相和所述富稀土相的体积之和中所占百分比。 Wherein, the volume fraction of R 6 Fe 13 Ga is preferably 2.5 to 10.8%, for example 2.5%, 3.2%, 3.4%, 4.6%, 4.8%, 5.7%, 6.3%, 6.4%, 6.5%, 6.7% %, 7.2%, 7.3%, 7.6%, 7.7%, 7.8%, 7.9%, 8.4%, 8.5%, 8.8%, 10.5% or 10.8%; wherein the percentage refers to the R 6 Fe 13 Ga The volume accounts for the percentage of the total volume of the grain boundary phase, the R 2 Fe 14 B main phase, and the rare earth-rich phase.
本发明还提供了一种如前所述的R-T-B系永磁材料的制备方法,其步骤包括:将R-T-B系永磁材料的原料依次进行熔炼、铸造、氢破、气流磨、成型、烧结和时效,即可。The present invention also provides a method for preparing the RTB-based permanent magnet material as described above, and the steps include: sequentially smelting, casting, hydrogen breaking, jet milling, forming, sintering and aging of the raw materials of the RTB-based permanent magnet material. , You can.
本发明中,所述R-T-B系永磁材料的原料,本领域技术人员知晓为满足如前所述R-T-B系永磁材料的元素含量质量百分比的原料。In the present invention, the raw material of the R-T-B-based permanent magnetic material is known to those skilled in the art as the raw material that satisfies the element content of the R-T-B-based permanent magnetic material as described above.
本发明中,所述熔炼的操作和条件可为本领域常规。In the present invention, the operation and conditions of the smelting can be conventional in the art.
较佳地,在高频真空熔炼炉中,将所述原料熔炼。Preferably, the raw materials are smelted in a high-frequency vacuum melting furnace.
较佳地,所述熔炼炉的真空度小于0.1Pa,更佳地小于0.02Pa。Preferably, the vacuum degree of the smelting furnace is less than 0.1 Pa, more preferably less than 0.02 Pa.
较佳地,所述熔炼的温度为1450~1550℃,更佳地为1500~1550℃。Preferably, the melting temperature is 1450-1550°C, more preferably 1500-1550°C.
本发明中,所述铸造的操作和条件可为本领域常规,一般在惰性气氛中进行,得到R-T-B系永磁材料合金铸片。例如:在Ar气氛中(例如5.5×10 4Pa的Ar气氛下),以10 2℃/秒-10 4℃/秒的速度冷却,即可。所述冷却可通过铜辊中通入冷却水实现。优选地,所述铜辊的进水温度≤25℃,例如为23.1℃、23.3℃、23.4℃、23.5℃、23.6℃、23.7℃、23.8℃或24.2℃。 In the present invention, the operation and conditions of the casting can be conventional in the art, and are generally carried out in an inert atmosphere to obtain an alloy cast piece of RTB-based permanent magnet material. For example: in an Ar atmosphere (e.g. under Ar atmosphere of 5.5 × 10 4 Pa), at a rate of 10 2 ℃ / sec -10 4 ℃ / sec cooling can. The cooling can be achieved by passing cooling water into the copper roller. Preferably, the water inlet temperature of the copper roller is ≤ 25°C, for example, 23.1°C, 23.3°C, 23.4°C, 23.5°C, 23.6°C, 23.7°C, 23.8°C or 24.2°C.
本发明中,所述氢破的操作和条件可为本领域常规。一般情况下,所述氢破包括氢吸附过程和脱氢过程,可将所述R-T-B系永磁材料合金铸片进行氢破处理,获得R-T-B系永磁材料合金粉体。In the present invention, the operation and conditions of the hydrogen breaker can be conventional in the art. In general, the hydrogen destruction includes a hydrogen adsorption process and a dehydrogenation process, and the R-T-B series permanent magnet material alloy cast piece can be subjected to hydrogen destruction treatment to obtain R-T-B series permanent magnet material alloy powder.
较佳地,所述氢破的吸氢温度为20~300℃,例如为25℃。Preferably, the hydrogen absorption temperature of the hydrogen breaker is 20 to 300°C, for example, 25°C.
较佳地,所述氢破的吸氢压力为0.12~0.19MPa,例如为0.19MPa。Preferably, the hydrogen absorption pressure of the hydrogen breaker is 0.12 to 0.19 MPa, for example, 0.19 MPa.
较佳地,所述氢破的脱氢时间为0.5~5h,例如为2h。Preferably, the dehydrogenation time of the hydrogen breaking is 0.5-5h, for example 2h.
较佳地,所述氢破的脱氢温度为450~600℃,例如为550℃。Preferably, the dehydrogenation temperature of the hydrogen breakdown is 450-600°C, for example, 550°C.
本发明中,所述气流磨的操作和条件可为本领域常规。较佳地,所述气流磨为将所述R-T-B系永磁材料合金粉体送入气流磨机进行气流磨继续破碎,得到R-T-B系永磁材料细粉。In the present invention, the operation and conditions of the jet mill can be conventional in the art. Preferably, the jet mill is to send the R-T-B series permanent magnet material alloy powder to the jet mill for jet milling to continue to be crushed to obtain the R-T-B series permanent magnet material fine powder.
更佳地,所述气流磨中气流磨机的磨室中含氧量在120ppm以下。More preferably, the oxygen content in the grinding chamber of the jet mill in the jet mill is below 120 ppm.
更佳地,所述气流磨中分选轮的转速为3500~4300rpm/min,优选为3900~4100rpm/min,例如为4000rpm/min。More preferably, the rotation speed of the sorting wheel in the jet mill is 3500-4300 rpm/min, preferably 3900-4100 rpm/min, for example 4000 rpm/min.
更佳地,所述气流磨的研磨压力为0.3~0.5MPa,例如为0.4MPa。More preferably, the grinding pressure of the jet mill is 0.3-0.5 MPa, for example 0.4 MPa.
更佳地,所述R-T-B系永磁材料细粉的中值粒径D50为3~5.5μm,例如为4μm。More preferably, the median particle size D50 of the fine powder of the R-T-B permanent magnetic material is 3 to 5.5 μm, for example, 4 μm.
本发明中,所述成型的操作和条件可为本领域常规。In the present invention, the molding operation and conditions can be conventional in the art.
较佳地,所述成型在1.8T以上的,例如为1.8T的磁场强度和氮气气氛保护下进行。Preferably, the molding is performed at a magnetic field strength above 1.8T, such as 1.8T, and under the protection of a nitrogen atmosphere.
本发明中,所述烧结的操作和条件可为本领域常规。In the present invention, the sintering operation and conditions can be conventional in the art.
较佳地,所述烧结的温度为900~1300℃,更佳地为1000~1100℃,例如为1050℃、1055℃、1065℃、1070℃、1075℃、1080℃、1085℃、1087℃、1088℃或1090℃。Preferably, the sintering temperature is 900 to 1300°C, more preferably 1000 to 1100°C, such as 1050°C, 1055°C, 1065°C, 1070°C, 1075°C, 1080°C, 1085°C, 1087°C, 1088°C or 1090°C.
较佳地,所述烧结的时间为5~10h,例如为8h。Preferably, the sintering time is 5-10h, for example 8h.
本发明中,所述时效的操作和条件可为本领域常规。In the present invention, the aging operation and conditions can be conventional in the art.
较佳地,所述时效包含一级时效和二级时效。Preferably, the aging includes primary aging and secondary aging.
更佳地,所述一级时效的温度为850℃~950℃,例如为900℃。More preferably, the temperature of the primary aging is 850°C to 950°C, for example, 900°C.
更佳地,所述二级时效温度为430℃~560℃,优选地为460~490℃,例如为460℃、470℃、475℃、477℃或480℃。More preferably, the secondary aging temperature is 430°C to 560°C, preferably 460 to 490°C, for example, 460°C, 470°C, 475°C, 477°C or 480°C.
更佳地,所述一级时效处理的时间为2~5h,例如为3h。More preferably, the time of the primary aging treatment is 2 to 5 hours, for example, 3 hours.
更佳地,所述二级时效处理的时间为2~5h,例如为3h。More preferably, the time of the secondary aging treatment is 2 to 5 hours, for example, 3 hours.
本发明还提供了一种如前所述的R-T-B系永磁材料在汽车转子、汽车驱动电机、风电或水泵中的应用。The invention also provides an application of the aforementioned R-T-B series permanent magnet material in automobile rotors, automobile drive motors, wind power or water pumps.
在符合本领域常识的基础上,上述各优选条件,可任意组合,即得本发明各较佳实例。On the basis of conforming to common knowledge in the field, the above-mentioned preferred conditions can be combined arbitrarily to obtain preferred embodiments of the present invention.
本发明所用试剂和原料均市售可得。The reagents and raw materials used in the present invention are all commercially available.
本发明的积极进步效果在于:The positive and progressive effects of the present invention are:
(1)本发明中,R-T-B系永磁材料的配方设计为B含量低、Ga含量高、不含Al(制备过程中使用的设备和/或原材料中极少量的杂质)且不含Co。(1) In the present invention, the formula of the R-T-B permanent magnet material is designed to be low in B content, high in Ga content, free of Al (a very small amount of impurities in the equipment and/or raw materials used in the preparation process) and free of Co.
(2)本发明中,R-T-B系永磁材料的矫顽力Hcj(≥16.61kOe)和Br (≥11.73kGs)高,添加重稀土元素后,Hcj可达29.24kOe以上,磁体温度稳定性好,性能优异;且其退磁曲线无台阶,相对磁导率低,矫顽力同批次极差≤1.5kOe,磁钢均一性好(方形度≥97%)。(2) In the present invention, the coercivity Hcj (≥16.61kOe) and Br (≥11.73kGs) of the RTB-based permanent magnet material are high. After adding heavy rare earth elements, Hcj can reach more than 29.24kOe, and the temperature stability of the magnet is good. Excellent performance; and its demagnetization curve has no steps, the relative permeability is low, the coercive force is less than 1.5kOe in the same batch, and the magnetic steel has good uniformity (squareness ≥97%).
(3)由于Co作为战略元素,普通的工艺中通过Co的添加目的是保证剩磁的高温稳定性,然而,本发明的配方设计能够使得R-T-B系永磁材料在不添加Co的基础上,实现了和添加Co元素相当的温度稳定性。(3) Since Co is a strategic element, the purpose of adding Co in ordinary processes is to ensure the high-temperature stability of remanence. However, the formulation design of the present invention can enable RTB-based permanent magnet materials to achieve The temperature stability is equivalent to the addition of Co.
具体实施方式Detailed ways
下面通过实施例的方式进一步说明本发明,但并不因此将本发明限制在所述的实施例范围之中。下列实施例中未注明具体条件的实验方法,按照常规方法和条件,或按照商品说明书选择。The present invention will be further described by way of examples below, but the present invention is not limited to the scope of the described examples. In the following examples, the experimental methods without specific conditions are selected according to conventional methods and conditions, or according to the product specification.
实施例1Example 1
本实施例中制备R-T-B系永磁材料所用的原料如表1所示,其制备的工艺如下:The raw materials used in the preparation of the R-T-B series permanent magnet material in this embodiment are shown in Table 1, and the preparation process is as follows:
(1)熔炼:按表1所示配方,取配制好的原料放入氧化铝制的坩埚中,在高频真空感应熔炼炉中在真空度小于0.02Pa的条件下,以1500℃的温度进行真空熔炼。(1) Smelting: According to the formula shown in Table 1, take the prepared raw materials and put them in a crucible made of alumina, and carry out at a temperature of 1500℃ in a high-frequency vacuum induction melting furnace under the condition of a vacuum of less than 0.02Pa Vacuum melting.
(2)铸造过程:在真空熔炼后的熔炼炉中通入Ar气体使气压达到5.5万Pa后,进行铸造,将熔融液通过29转/分转速的铜辊制得0.12-0.35mm厚度的速凝合金片,浇铸过程中,铜辊需通入冷冻水,其进水温度≤25℃(如表2所示);以10 2℃/秒-10 4℃/秒的冷却速度获得急冷合金。 (2) Casting process: Ar gas is introduced into the smelting furnace after vacuum smelting to make the pressure reach 55,000 Pa, and then the casting is carried out. The molten liquid is passed through a copper roller with a rotation speed of 29 rpm to obtain a thickness of 0.12-0.35 mm. condensate alloy sheet, the casting process, the copper roll should be purged with chilled water, which inlet temperature ≤25 ℃ (table 2); at a cooling rate of 10 2 ℃ / sec -10 4 ℃ / sec is obtained rapidly solidified alloy.
(3)氢破:R-T-B合金铸片的氢吸附过程的吸氢温度为25℃;吸氢压力为0.19MPa。(3) Hydrogen breaking: The hydrogen absorption temperature in the hydrogen adsorption process of the R-T-B alloy cast piece is 25°C; the hydrogen absorption pressure is 0.19 MPa.
氢破的脱氢时间为2h。脱氢温度为550℃,获得R-T-B合金粉体。The dehydrogenation time of hydrogen breakdown is 2h. The dehydrogenation temperature is 550°C to obtain R-T-B alloy powder.
(3)气流磨:将所述R-T-B合金粉体送入气流磨机进行气流磨继续破碎,得到R-T-B细粉。(3) Jet mill: The R-T-B alloy powder is sent to the jet mill for jet milling to continue to be crushed to obtain R-T-B fine powder.
气流磨中气流磨机的磨室中含氧量在120ppm以下。The oxygen content in the grinding chamber of the jet mill in the jet mill is below 120 ppm.
气流磨中分选轮的转速为4000rpm/min。The speed of the sorting wheel in the jet mill is 4000 rpm/min.
气流磨的研磨压力为0.4MPa。The grinding pressure of the jet mill is 0.4MPa.
得到的R-T-B细粉的中值粒径D50为4μm。The median particle diameter D50 of the obtained R-T-B fine powder was 4 μm.
(4)成型:细粉在一定磁场强度下经取向成型得到压坯。(4) Forming: The fine powder is oriented and formed under a certain magnetic field strength to obtain a compact.
成型在1.8T的磁场强度和氮气气氛保护下进行。The molding is carried out under the protection of 1.8T magnetic field strength and nitrogen atmosphere.
(5)烧结:烧结的温度(如表2所示)为1090℃,(5) Sintering: the sintering temperature (as shown in Table 2) is 1090℃,
烧结的时间为8h。The sintering time is 8h.
(6)时效(6) Limitation
一级时效的温度为900℃;二级时效的温度(如表2所示)为470℃。The temperature of primary aging is 900°C; the temperature of secondary aging (as shown in Table 2) is 470°C.
一级时效的处理时间为3h,二级时效的处理时间为3h。The treatment time of primary aging is 3h, and the treatment time of secondary aging is 3h.
表1各实施例、对比例中原料质量百分比Table 1 The mass percentage of raw materials in each embodiment and comparative example
Figure PCTCN2021077195-appb-000001
Figure PCTCN2021077195-appb-000001
Figure PCTCN2021077195-appb-000002
Figure PCTCN2021077195-appb-000002
实施例2~24、对比例1~8Examples 2-24, Comparative Examples 1-8
按表1所示配方配制原料,除表2所示条件外,其他工艺条件均同实施例1,制得R-T-B系永磁材料。The raw materials were prepared according to the formula shown in Table 1, and except for the conditions shown in Table 2, the other process conditions were the same as those in Example 1, and the R-T-B series permanent magnet material was prepared.
表2Table 2
编号/wt%Number/wt% 铸造过程中冷却水温度Cooling water temperature during casting 烧结温度Sintering temperature 二级时效温度Secondary aging temperature
实施例1Example 1 23.523.5 10901090 470470
实施例2Example 2 23.323.3 10801080 480480
实施例3Example 3 23.123.1 10651065 477477
实施例4Example 4 24.224.2 10701070 475475
实施例5Example 5 23.623.6 10901090 480480
实施例6Example 6 23.823.8 10901090 470470
实施例7Example 7 23.823.8 10871087 460460
实施例8Example 8 23.423.4 10851085 480480
实施例9Example 9 23.723.7 10881088 477477
实施例10Example 10 23.823.8 10901090 475475
实施例11Example 11 23.623.6 10551055 480480
实施例12Example 12 23.323.3 10851085 470470
实施例13Example 13 23.123.1 10851085 460460
实施例14Example 14 24.224.2 10701070 480480
实施例15Example 15 23.623.6 10651065 477477
实施例16Example 16 23.823.8 10701070 475475
实施例17Example 17 23.823.8 10851085 480480
实施例18Example 18 23.423.4 10751075 470470
实施例19Example 19 23.723.7 10851085 460460
实施例20Example 20 23.323.3 10701070 480480
实施例21Example 21 23.123.1 10651065 477477
实施例22Example 22 24.224.2 10701070 475475
实施例23Example 23 23.623.6 10501050 480480
实施例24Example 24 23.823.8 10501050 470470
对比例1Comparative example 1 23.823.8 10701070 490490
对比例2Comparative example 2 23.423.4 10801080 500500
对比例3Comparative example 3 23.723.7 10851085 510510
对比例4Comparative example 4 23.823.8 10651065 500500
对比例5Comparative example 5 23.623.6 10351035 490490
对比例6Comparative example 6 23.723.7 10951095 490490
对比例7Comparative example 7 23.823.8 10701070 495495
对比例8Comparative example 8 23.623.6 10851085 495495
效果实施例Example of effects
(1)成分测定(1) Composition determination
实施例1~24、对比例1~8的样品使用高频电感耦合等离子体发射光谱仪(ICP-OES,Horiba)测定具体成分。下表所示为成分检测结果。The samples of Examples 1-24 and Comparative Examples 1-8 were measured for specific components using a high-frequency inductively coupled plasma emission spectrometer (ICP-OES, Horiba). The following table shows the component test results.
表3table 3
Figure PCTCN2021077195-appb-000003
Figure PCTCN2021077195-appb-000003
Figure PCTCN2021077195-appb-000004
Figure PCTCN2021077195-appb-000004
需要说明的是,表3中烧结磁体中Al的含量是原料中的Al以及在其他原料和工艺(例如熔炼过程中氧化铝制的坩埚)中引入的Al的含量之和。It should be noted that the content of Al in the sintered magnet in Table 3 is the sum of the content of Al in the raw material and the content of Al introduced in other raw materials and processes (for example, a crucible made of alumina during smelting).
(2)磁性能检测(2) Magnetic performance testing
磁性能评价:实施例1~24、对比例1~8的样品使用中国计量院的NIM-10000H型BH大块稀土永磁无损测量系统进行磁性能检测。磁性能检测样品大小为10mm*10mm的圆柱,下表所示为磁性能检测结果。Magnetic performance evaluation: The samples of Examples 1-24 and Comparative Examples 1-8 were tested for magnetic performance using the NIM-10000H BH bulk rare earth permanent magnet non-destructive measurement system of China Metrology Institute. The magnetic performance test sample size is a cylinder of 10mm*10mm. The following table shows the magnetic performance test results.
表4Table 4
Figure PCTCN2021077195-appb-000005
Figure PCTCN2021077195-appb-000005
Figure PCTCN2021077195-appb-000006
Figure PCTCN2021077195-appb-000006
注:表4中6-13-1相是指RE 6Fe 13Ga相,其中:6-13-1相所占整体物相的体积比是指RE 6Fe 13Ga相在整体物相中的体积比,整体物相包括晶界相、R 2Fe 14B主相和富稀土相。对比例1~8中R-T-B系永磁材料的磁性能为对比例1~8的配方经工艺优化(进水温度、烧结温度、时效温度)后所能够获得的最佳性能。 Note: The 6-13-1 phase in Table 4 refers to the RE 6 Fe 13 Ga phase, in which: the volume ratio of the 6-13-1 phase to the overall phase refers to the RE 6 Fe 13 Ga phase in the overall phase By volume ratio, the overall phase includes grain boundary phase, R 2 Fe 14 B main phase and rare earth-rich phase. The magnetic properties of the RTB-based permanent magnet materials in Comparative Examples 1 to 8 are the best properties that can be obtained after the formulations of Comparative Examples 1 to 8 are optimized by process (water inlet temperature, sintering temperature, aging temperature).
1、6-13-1相的检测方法:1. Detection method of phase 6-13-1:
微观结构:采用FE-EPMA检测,对R-T-B系永磁材料的垂直取向面进行抛光,采用场发射电子探针显微分析仪(FE-EPMA)(日本电子株式会社(JEOL),8530F)检测。检测晶界中的R6T13M相,T指Fe,M指Ga。Microstructure: FE-EPMA is used to detect, the vertical orientation surface of R-T-B series permanent magnetic material is polished, and the field emission electron probe microanalyzer (FE-EPMA) (JEOL, 8530F) is used to detect. Detect the R6T13M phase in the grain boundary, T refers to Fe, and M refers to Ga.
2、表4中,Br或Hcj均是指均值:通过测试同一批次中5份稀土永磁材料样品(圆柱10mm*10mm)的剩磁或矫顽力,计算出的平均值。2. In Table 4, Br or Hcj refer to the average value: the average value calculated by testing the remanence or coercivity of 5 rare earth permanent magnetic material samples (cylinder 10mm*10mm) in the same batch.
6-13-1相所占整体物相的体积比以及温度系数也是通过测量同一批次中的5份稀土永磁材料样品(圆柱10mm*10mm)的性能所取的平均值后再取的绝对值。The volume ratio and temperature coefficient of the 6-13-1 phase in the overall phase are also taken after measuring the average value of the performance of 5 rare earth permanent magnetic material samples (cylinder 10mm*10mm) in the same batch. value.
本发明每一实施例和对比例中制备出的是若干个磁体,同一批次指的就是每一实施例和对比例中所获得的磁体材料按照性能测试的单位切割得到的样品。In each embodiment and comparative example of the present invention, several magnets are prepared, and the same batch refers to the sample obtained by cutting the magnet material obtained in each embodiment and comparative example according to the unit of the performance test.
(3)磁性能一致性检测(3) Magnetic performance consistency test
方形度=Hk/Hcj;其中,Hk为当Br为90%Br时,外磁场H的值,Hcj为矫顽力。Squareness=Hk/Hcj; where Hk is the value of the external magnetic field H when Br is 90% Br, and Hcj is the coercivity.
相对磁导率为Br/Hcb;其中,Br为剩磁,Hcb为磁感矫顽力,当J-H曲线存在拐点时,磁导率在拐点之前取值。通过测试同一批次中5份稀土永磁材料样品的剩磁和磁感矫顽力,计算出的平均值。The relative permeability is Br/Hcb; among them, Br is the remanence and Hcb is the magnetic coercivity. When the J-H curve has an inflection point, the permeability is taken before the inflection point. The average value calculated by testing the remanence and magnetic induction coercivity of 5 rare earth permanent magnetic material samples in the same batch.
Max(Hcj)-Min(Hcj):同一批次产品中矫顽力最大值减去矫顽力最小值,若大于1.5kOe,则是磁性能一致性差。Max(Hcj)-Min(Hcj): The maximum value of the coercive force minus the minimum value of the coercive force in the same batch of products. If it is greater than 1.5kOe, the magnetic performance consistency is poor.
下表所示为磁性能一致性检测结果。The following table shows the results of magnetic consistency testing.
表5table 5
Figure PCTCN2021077195-appb-000007
Figure PCTCN2021077195-appb-000007
Figure PCTCN2021077195-appb-000008
Figure PCTCN2021077195-appb-000008
Figure PCTCN2021077195-appb-000009
Figure PCTCN2021077195-appb-000009

Claims (10)

  1. 一种R-T-B系永磁材料,其特征在于,其包含:R、Ga、Al、Fe和B,还包含Ti、Zr和Nb的一种或多种,以重量百分比计,其含量如下:An R-T-B series permanent magnet material, characterized in that it contains: R, Ga, Al, Fe and B, and also contains one or more of Ti, Zr and Nb, and its content is as follows in weight percentage:
    R的含量为28.5~33.05%;所述R为至少含有Nd的稀土元素;The content of R is 28.5-33.05%; said R is a rare earth element containing at least Nd;
    Ga的含量大于0.35%;The content of Ga is greater than 0.35%;
    B的含量为0.84~0.945%;The content of B is 0.84~0.945%;
    Al的含量小于0.08%;The content of Al is less than 0.08%;
    当所述R-T-B系永磁材料包含Ti时,所述Ti的含量为0.145~0.255%;When the R-T-B series permanent magnetic material contains Ti, the content of Ti is 0.145-0.255%;
    当所述R-T-B系永磁材料包含Zr时,所述Zr的含量为0.185~0.355%;When the R-T-B series permanent magnetic material contains Zr, the content of the Zr is 0.185-0.355 %;
    当所述R-T-B系永磁材料包含Nb时,所述Nb的含量为0.195~0.505%;When the R-T-B series permanent magnet material contains Nb, the content of Nb is 0.195 to 0.505%;
    所述R-T-B系永磁材料中不含有Co。The R-T-B-based permanent magnet material does not contain Co.
  2. 如权利要求1所述的R-T-B系永磁材料,其特征在于,以重量百分比计,所述Ga的含量为0.35%<Ga<0.55%,或者0.55wt%≤Ga<1.05wt%,或者1.05wt%≤Ga<1.25wt%,或者Ga≥1.25wt%,例如为0.398%、0.552%、0.602%、0.703%、0.704%、0.791%、0.802%、0.804%、0.987%、1.052%、1.053%、1.101%、1.103%、1.203%、1.253%、1.303%、1.304%、1.505%或1.789%;The RTB-based permanent magnet material of claim 1, wherein the Ga content is 0.35%<Ga<0.55%, or 0.55wt%≤Ga<1.05wt%, or 1.05wt% in terms of weight percentage. %≤Ga<1.25wt%, or Ga≥1.25wt%, such as 0.398%, 0.552%, 0.602%, 0.703%, 0.704%, 0.791%, 0.802%, 0.804%, 0.987%, 1.052%, 1.053%, 1.101%, 1.103%, 1.203%, 1.253%, 1.303%, 1.304%, 1.505% or 1.789%;
    和/或,以重量百分比计,所述B的含量为0.915%~0.94%;And/or, in terms of weight percentage, the content of B is 0.915% to 0.94%;
    或者,以重量百分比计,所述B的含量为0.844%、0.845%、0.863%、0.883%、0.893%、0.901%、0.904%、0.922%、0.923%、0.924%、0.925%、0.942%或0.943%;Or, in terms of weight percentage, the content of B is 0.844%, 0.845%, 0.863%, 0.883%, 0.893%, 0.901%, 0.904%, 0.922%, 0.923%, 0.924%, 0.925%, 0.942%, or 0.943 %;
    或者,所述B的含量≥0.915wt%和5.55at%中的大者;其中,所述wt%为重量百分比,所述at%为原子百分比;Or, the content of B is greater than or equal to 0.915 wt% and 5.55 at%; wherein, the wt% is a weight percentage, and the at% is an atomic percentage;
    和/或,以重量百分比计,所述Al的含量为0.03%≤Al<0.05%,或者,所述Al的含量小于0.03%,例如为0.031%、0.032%、0.033%、0.038%、0.039%、0.041%、0.042%、0.048%或0.049%;And/or, in terms of weight percentage, the content of Al is 0.03%≤Al<0.05%, or the content of Al is less than 0.03%, such as 0.031%, 0.032%, 0.033%, 0.038%, 0.039% , 0.041%, 0.042%, 0.048% or 0.049%;
    和/或,当所述R-T-B系永磁材料包含Ti时,以重量百分比计,所述Ti的含量为0.149%~0.254%,例如为0.149%、0.152%、0.153%、0.154%、0.156%、 0.204%、0.205%或0.254%;And/or, when the RTB-based permanent magnetic material contains Ti, the content of Ti is 0.149% to 0.254%, for example, 0.149%, 0.152%, 0.153%, 0.154%, 0.156%, and 0.204%, 0.205% or 0.254%;
    和/或,当所述R-T-B系永磁材料包含Zr时,以重量百分比计,所述Zr的含量为0.2%≤Zr<(3.48B-2.67)%,优选地为0.26%≤Zr<(3.48B-2.67)%;And/or, when the RTB-based permanent magnet material contains Zr, the content of Zr is 0.2%≤Zr<(3.48B-2.67)%, preferably 0.26%≤Zr<(3.48 B-2.67)%;
    和/或,当所述R-T-B系永磁材料包含Zr时,以重量百分比计,所述Zr的含量为0.189%~0.353%,例如为0.189%、0.198%、0.252%、0.262%、0.263%、0.291%、0.297%、0.301%、0.303%、0.329%、0.348%、0.352%或0.353%;And/or, when the RTB-based permanent magnet material contains Zr, the content of Zr is 0.189%-0.353%, for example, 0.189%, 0.198%, 0.252%, 0.262%, 0.263%, 0.291%, 0.297%, 0.301%, 0.303%, 0.329%, 0.348%, 0.352% or 0.353%;
    和/或,当所述R-T-B系永磁材料包含Nb时,以重量百分比计,所述Nb的含量为0.198%~0.505%,例如为0.198%、0.201%、0.202%、0.204%、0.205%、0.206%、0.304%、0.404%或0.505%。And/or, when the RTB-based permanent magnetic material contains Nb, the content of Nb is 0.198% to 0.505%, for example, 0.198%, 0.201%, 0.202%, 0.204%, 0.205%, and 0.206%, 0.304%, 0.404% or 0.505%.
  3. 如权利要求1所述的R-T-B系永磁材料,其特征在于,所述R-T-B系永磁材料包含R 2Fe 14B主相、晶界相和富稀土相; The RTB-based permanent magnetic material of claim 1, wherein the RTB-based permanent magnetic material comprises a main phase of R 2 Fe 14 B, a grain boundary phase, and a rare earth-rich phase;
    其中,所述晶界相优选地包含R 6Fe 13Ga; Wherein, the grain boundary phase preferably includes R 6 Fe 13 Ga;
    其中,所述R 6Fe 13Ga的体积分数优选地为2.5~10.8%,例如为2.5%、3.2%、3.4%、4.6%、4.8%、5.7%、6.3%、6.4%、6.5%、6.7%、7.2%、7.3%、7.6%、7.7%、7.8%、7.9%、8.4%、8.5%、8.8%、10.5%或10.8%;其中,所述百分比是指所述R 6Fe 13Ga的体积在所述晶界相、所述R 2Fe 14B主相和所述富稀土相的体积之和中所占百分比。 Wherein, the volume fraction of R 6 Fe 13 Ga is preferably 2.5 to 10.8%, for example 2.5%, 3.2%, 3.4%, 4.6%, 4.8%, 5.7%, 6.3%, 6.4%, 6.5%, 6.7% %, 7.2%, 7.3%, 7.6%, 7.7%, 7.8%, 7.9%, 8.4%, 8.5%, 8.8%, 10.5% or 10.8%; wherein the percentage refers to the R 6 Fe 13 Ga The volume accounts for the percentage of the total volume of the grain boundary phase, the R 2 Fe 14 B main phase, and the rare earth-rich phase.
  4. 如权利要求1所述的R-T-B系永磁材料,其特征在于,以重量百分比计,所述R的含量为28.5~33.015%,例如为28.5%、28.504%、28.508%、28.509%、28.708%、29.187%、29.6%、29.703%、29.904%、29.992%、30.097%、30.196%、30.401%、30.61%、31.013%、31.504%、31.696%、31.704%、31.806%、31.998%、32.21%或33.015%;The RTB-based permanent magnet material of claim 1, wherein the content of R is 28.5% to 33.015% by weight percentage, such as 28.5%, 28.504%, 28.508%, 28.509%, 28.708%, 29.187%, 29.6%, 29.703%, 29.904%, 29.992%, 30.097%, 30.196%, 30.401%, 30.61%, 31.013%, 31.504%, 31.696%, 31.704%, 31.806%, 31.998%, 32.21% or 33.015% ;
    和/或,以重量百分比计,所述Nd的含量为9.602~32.907%,例如为9.602%、10.983%、11.506%、14.605%、14.98%、28.205%、28.297%、28.495%、28.504%、28.509%、29.404%、29.595%、29.703%、29.904%、30.196%、30.204%、30.205%、31.013%、31.504%、31.508%、31.806%、32.012%或32.907%;And/or, by weight percentage, the Nd content is 9.602-32.907%, for example, 9.602%, 10.983%, 11.506%, 14.605%, 14.98%, 28.205%, 28.297%, 28.495%, 28.504%, 28.509 %, 29.404%, 29.595%, 29.703%, 29.904%, 30.196%, 30.204%, 30.205%, 31.013%, 31.504%, 31.508%, 31.806%, 32.012% or 32.907%;
    和/或,所述R中包含Pr;And/or, the R includes Pr;
    其中,以重量百分比计,所述Pr的含量优选地为小于0.5%,或者大于17%,例如为0.108%、0.196%、0.197%、0.198%、0.203%、0.205%、0.303%、0.394%、0.397%、0.405%、17.018%、17.605%、18.197%、18.204%或19.106%;Wherein, in terms of weight percentage, the content of Pr is preferably less than 0.5%, or greater than 17%, such as 0.108%, 0.196%, 0.197%, 0.198%, 0.203%, 0.205%, 0.303%, 0.394%, 0.397%, 0.405%, 17.018%, 17.605%, 18.197%, 18.204% or 19.106%;
    和/或,所述R中包含重稀土元素RH;And/or, the R contains a heavy rare earth element RH;
    其中,所述RH优选地为Gd、Tb、Dy、Ho、Er、Tm、Yb、Lu和Y的一种或多种;Wherein, the RH is preferably one or more of Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu and Y;
    其中,以重量百分比计,所述RH的含量优选地为1.5~6.0%,例如为2.987%或3.012%;Wherein, in terms of weight percentage, the content of the RH is preferably 1.5-6.0%, for example, 2.987% or 3.012%;
    和/或,以重量百分比计,所述Fe的含量为余量;And/or, in terms of weight percentage, the content of Fe is the balance;
    优选地,以重量百分比计,所述Fe的含量为64.5%~69.6%,例如为64.707%、65.367%、65.392%、65.473%、65.568%、65.837%、66.01%、66.187%、66.198%、66.199%、66.557%、66.782%、67.114%、67.468%、67.621%、67.797%、68.118%、68.637%、68.792%、68.794%、69.21%、69.258%、69.486%或69.573%。Preferably, in terms of weight percentage, the content of Fe is 64.5% to 69.6%, for example 64.707%, 65.367%, 65.392%, 65.473%, 65.568%, 65.837%, 66.01%, 66.187%, 66.198%, 66.199 %, 66.557%, 66.782%, 67.114%, 67.468%, 67.621%, 67.797%, 68.118%, 68.637%, 68.792%, 68.794%, 69.21%, 69.258%, 69.486% or 69.573%.
  5. 如权利要求1所述的R-T-B系永磁材料,其特征在于,以原子百分比计,当所述R中包含Pr时,B/(Pr+Nd)≥0.405;The R-T-B series permanent magnetic material according to claim 1, wherein, in terms of atomic percentage, when Pr is contained in said R, B/(Pr+Nd)≥0.405;
    和/或,以原子百分比计,Ga>7.2941-1.24B;And/or, in atomic percentage, Ga>7.2941-1.24B;
    和/或,以原子百分比计,B/R≥0.38;And/or, in atomic percentage, B/R≥0.38;
    和/或,所述R-T-B系永磁材料中不含有Cu。And/or, the R-T-B-based permanent magnet material does not contain Cu.
  6. 一种如权利要求1~5中任一项所述的R-T-B系永磁材料的制备方法,其特征在于,其步骤包括:将R-T-B系永磁材料的原料依次进行熔炼、铸造、氢破、气流磨、成型、烧结和时效,即可。A method for preparing RTB-based permanent magnet materials according to any one of claims 1 to 5, characterized in that the steps include: smelting, casting, hydrogen breaking, and airflow of the raw materials of RTB-based permanent magnet materials in sequence Grinding, forming, sintering and aging, that's all.
  7. 如权利要求6所述的制备方法,其特征在于,所述铸造的工艺按下述步骤进行:在Ar气氛中,以10 2℃/秒-10 4℃/秒的速度冷却,即可;所述冷却通过铜辊中通入冷却水实现,优选地,所述铜辊的进水温度≤25℃,例如为23.1℃、23.3℃、23.4℃、23.5℃、23.6℃、23.7℃、23.8℃或24.2℃; The method of preparation according to claim 6, characterized in that the casting process carried out by the following steps: in an Ar atmosphere at a rate of 10 2 ℃ / sec -10 4 ℃ / sec cooling can; the The cooling is achieved by passing cooling water into the copper roller. Preferably, the water inlet temperature of the copper roller is ≤ 25°C, for example, 23.1°C, 23.3°C, 23.4°C, 23.5°C, 23.6°C, 23.7°C, 23.8°C or 24.2℃;
    和/或,所述烧结的温度为900~1300℃,较佳地为1000~1100℃,例如为1050℃、1055℃、1065℃、1070℃、1075℃、1080℃、1085℃、1087℃、 1088℃或1090℃;And/or, the sintering temperature is 900 to 1300°C, preferably 1000 to 1100°C, for example, 1050°C, 1055°C, 1065°C, 1070°C, 1075°C, 1080°C, 1085°C, 1087°C, 1088℃ or 1090℃;
    和/或,所述烧结的时间为5~10h,例如为8h;And/or, the sintering time is 5-10h, for example 8h;
    和/或,所述时效包含一级时效和二级时效。And/or, the aging includes a primary aging and a secondary aging.
  8. 如权利要求7所述的制备方法,其特征在于,所述一级时效的温度为850℃~950℃,例如为900℃;The preparation method according to claim 7, wherein the temperature of the primary aging is 850°C to 950°C, such as 900°C;
    和/或,所述二级时效温度为430℃~560℃,较佳地为460~490℃,例如为460℃、470℃、475℃、477℃或480℃;And/or, the secondary aging temperature is 430°C to 560°C, preferably 460 to 490°C, for example, 460°C, 470°C, 475°C, 477°C or 480°C;
    和/或,所述一级时效处理的时间为2~5h,例如为3h;And/or, the time of the primary aging treatment is 2 to 5 hours, for example, 3 hours;
    和/或,所述二级时效处理的时间为2~5h,例如为3h。And/or, the time of the secondary aging treatment is 2 to 5 hours, for example, 3 hours.
  9. 如权利要求6所述的制备方法,其特征在于,在高频真空熔炼炉中,将所述原料熔炼;The preparation method according to claim 6, wherein the raw material is smelted in a high-frequency vacuum melting furnace;
    和/或,所述熔炼炉的真空度小于0.1Pa,较佳地小于0.02Pa;And/or, the vacuum degree of the smelting furnace is less than 0.1 Pa, preferably less than 0.02 Pa;
    和/或,所述熔炼的温度为1450~1550℃,较佳地为1500~1550℃;And/or, the smelting temperature is 1450-1550°C, preferably 1500-1550°C;
    和/或,所述氢破的吸氢温度为20~300℃,例如为25℃;And/or, the hydrogen absorption temperature of the hydrogen breaker is 20 to 300°C, for example, 25°C;
    和/或,所述氢破的吸氢压力为0.12~0.19MPa,例如为0.19MPa;And/or, the hydrogen absorption pressure of the hydrogen breaker is 0.12 to 0.19 MPa, for example, 0.19 MPa;
    和/或,所述氢破的脱氢时间为0.5~5h,例如为2h;And/or, the dehydrogenation time of the hydrogen breaking is 0.5-5h, for example, 2h;
    和/或,所述氢破的脱氢温度为450~600℃,例如为550℃;And/or, the dehydrogenation temperature of the hydrogen breaking is 450-600°C, for example, 550°C;
    和/或,所述气流磨为将R-T-B系永磁材料合金粉体送入气流磨机进行气流磨继续破碎,得到R-T-B系永磁材料细粉;And/or, the jet mill is to send the R-T-B series permanent magnetic material alloy powder into the jet mill for jet milling to continue to be crushed to obtain the R-T-B series permanent magnetic material fine powder;
    较佳地,所述R-T-B系永磁材料细粉的中值粒径D50为3~5.5μm,例如为4μm;Preferably, the median diameter D50 of the R-T-B series permanent magnetic material fine powder is 3 to 5.5 μm, for example, 4 μm;
    和/或,所述气流磨中气流磨机的磨室中含氧量在120ppm以下;And/or, the oxygen content in the grinding chamber of the jet mill in the jet mill is below 120 ppm;
    和/或,所述气流磨中分选轮的转速为3500~4300rpm/min,较佳地为3900~4100rpm/min,例如为4000rpm/min;And/or, the rotation speed of the sorting wheel in the jet mill is 3500-4300rpm/min, preferably 3900-4100rpm/min, for example 4000rpm/min;
    和/或,所述气流磨的研磨压力为0.3~0.5MPa,例如为0.4MPa;And/or, the grinding pressure of the jet mill is 0.3-0.5 MPa, for example 0.4 MPa;
    和/或,所述成型在1.8T以上的,例如为1.8T的磁场强度和氮气气氛保护下进行。And/or, the molding is performed at a magnetic field strength above 1.8T, such as 1.8T, and under the protection of a nitrogen atmosphere.
  10. 一种如权利要求1~5中任一项所述的R-T-B系永磁材料在汽车转子、汽车驱动电机、风电或水泵中的应用。An application of the R-T-B series permanent magnet material according to any one of claims 1 to 5 in automobile rotors, automobile drive motors, wind power or water pumps.
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