WO2021244316A1

WO2021244316A1 - R-t-b-based permanent magnetic material, raw material composition, preparation method therefor and use thereof

Info

Publication number: WO2021244316A1
Application number: PCT/CN2021/095086
Authority: WO
Inventors: 蓝琴; 黄佳莹; 张艳艳
Original assignee: 厦门钨业股份有限公司; 福建省长汀金龙稀土有限公司
Priority date: 2020-06-03
Filing date: 2021-05-21
Publication date: 2021-12-09
Also published as: CN111613406A; CN111613406B

Abstract

Disclosed are an R-T-B-based permanent magnetic material, a raw material composition, a preparation method therefor and a use thereof. The raw material composition of the R-T-B-based permanent magnetic material contains the following components: R: 29.5-32%, R being a rare earth element containing at least Nd, and the content of Pr being 0-17%; Zr: 0.15- 0.50%; Ga: 0-1%, but not 0, and when the content of Ga is 0.21-0.46%, the content of Zr is 0.34-0.5%; Co: 0-0.3%; M: 0-3%, M being one or more of Al, Cu, Ti, Nb, Hf, Si, Sn, Ge, Ag, Au, Bi and Mn; B: 0.95-1.05%; and Fe: 64-70%. The percentage is the mass percentage of each component in the total mass of the raw material composition of the R-T-B-based permanent magnetic material, and the sum of the content of each component is 100%. The R-T-B-based permanent magnetic material of the present invention has the advantages of having a good squareness, a good high-temperature property and excellent mechanical properties.

Description

A kind of R-T-B series permanent magnet material, raw material composition and preparation method and application thereof

Technical field

The invention relates to an R-T-B series permanent magnet material, a raw material composition, and a preparation method and application thereof.

Background technique

The Nd-Fe-B permanent magnet material is based on Nd ₂ Fe _l4 B compound, which has the advantages of high magnetic properties, low thermal expansion coefficient, easy processing and low price. Since its introduction, it has grown at an average annual rate of 20-30%. Become the most widely used permanent magnet material. According to the preparation method, Nd-Fe-B permanent magnets can be divided into three types: sintering, bonding and hot pressing. Among them, sintered magnets account for more than 80% of the total output and are the most widely used.

In the prior art, when making heat-resistant and corrosion-resistant sintered Nd-Fe-B magnets, Co is the most used and most effective element. This is because the addition of Co can reduce the reversible temperature coefficient of magnetic induction, effectively increase the Curie temperature, and can improve the corrosion resistance of the Nd-Fe-B magnet. However, the addition of Co easily causes a sharp drop in remanence. At the same time, since the added Co is contained not only in the main phase but also in the grain boundary phase, the problem of reduced mechanical strength occurs, and the cost of Co is high.

In order to improve the magnetic properties, suppress the growth of crystal grains and improve the sintering temperature range, JP2002075717A adds Zr to the Cu-containing RTB rare earth permanent magnet, which makes the RTB rare earth containing Co, Al, Cu and containing Zr, Nb or Hf The fine ZrB compound, NbB compound or HfB compound (hereinafter referred to as MB compound) in the permanent magnet-like magnets are uniformly dispersed and precipitated. Among them, the average particle size of the MB compound is 5 μm or less, and the maximum interval between the MB compounds is 50 μm or less. JPWO2004030000A1 also adds Zr to the RTB-based rare earth permanent magnet, which uses a double alloy method to make _{the product of enrichment of Zr in the R 2} T ₁₄ B main phase, and clearly points out that if there is enrichment only in the grain boundary phase The product of Zr cannot solve its technical problems.

Summary of the invention

The technical problem to be solved by the present invention is to overcome the technical problem in the prior art that the RTB-based permanent magnetic material increases the Curie temperature and coercive force by adding Co, while Co faces the expensive defect, and provides an RTB Series permanent magnet materials, raw material compositions, and preparation methods and applications thereof. The invention does not add or control the content of trace Co, while controlling the content of Ga and Zr elements, the obtained R-T-B series permanent magnet material has the advantages of good squareness, good high temperature performance and excellent mechanical performance.

The present invention provides a raw material composition of R-T-B series permanent magnet material, which contains the following components in terms of mass percentage:

R, 29.5-32%, said R is a rare earth element containing at least Nd, and the content of Pr is 0-17%;

Zr, 0.15-0.50%;

Ga, 0-1%, but not 0, and when the content of Ga is 0.21-0.46%, the content of Zr is 0.34-0.5%;

Co, 0-0.3%;

M, 0-3%, the M is one or more of Al, Cu, Ti, Nb, Hf, Si, Sn, Ge, Ag, Au, Bi and Mn;

B, 0.95-1.05%;

Fe, 64-70%;

The percentage is the mass percentage of each component in the total mass of the raw material composition of the R-T-B permanent magnet material, and the sum of the content of each component is 100%.

In the raw material composition of the R-T-B permanent magnet material, the R may be a rare earth element added during a smelting process and/or a diffusion process, for example, a rare earth element added during a smelting process.

In the raw material composition of the RTB-based permanent magnet material, the content of R is, for example, 29.8%, 30.2%, 30.3%, 30.5% or 32%, wherein the percentage is the raw material composition of the RTB-based permanent magnet material Percentage of total mass.

In the raw material composition of the RTB-based permanent magnet material, the Nd content can be conventional in the art, preferably 21.9-30.1%, such as 21.9%, 22.3%, 22.7%, 22.8%, 23.6%, 23.8%, 23.9 %, 29.6% or 30.1%, wherein the percentage is the percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In the raw material composition of the RTB-based permanent magnetic material, the addition form of Nd in the R can be conventional in the art, for example, in the form of PrNd, or in the form of pure Nd, or in the form of pure Pr and Nd. In the form of a mixture of PrNd, or a combination of PrNd, pure Pr and Nd. When added in the form of PrNd, the mass ratio of Pr to Nd in PrNd is preferably 25:75, 20:80 or 10:90.

In the raw material composition of the RTB-based permanent magnet material, the content of Pr is preferably 0-10%, more preferably 0-8%, such as 0, 5.9%, 6%, 7.3%, 7.4%, 7.6% Or 8.0%, where the percentage is the percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In the raw material composition of the RTB-based permanent magnetic material, when the R contains Pr, the addition form of Pr can be conventional in the art, for example, in the form of PrNd, or in the form of pure Pr, or in the form of pure Pr. In the form of a mixture of Pr and Nd, or a combination of PrNd, pure Pr and Nd. When added in the form of PrNd, the mass ratio of Pr to Nd in PrNd is preferably 25:75, 20:80 or 10:90.

In the raw material composition of the R-T-B-based permanent magnet material, the R may further include a heavy rare earth element. The heavy rare earth element may be a heavy rare earth element added in a smelting process and/or a diffusion process. Preferably, the heavy rare earth element is a heavy rare earth element added in a smelting process.

In the raw material composition of the R-T-B permanent magnet material, the type of the heavy rare earth element may be a conventional heavy rare earth type in the art, such as one or more of Dy, Tb, Gd, and Ho.

In the raw material composition of the RTB-based permanent magnet material, when the R contains heavy rare earth elements, the content of the heavy rare earth elements can be conventional in the art, preferably 0-7% (excluding 0), and more preferably It is 0.1-0.6%, such as 0.1%, 0.2%, 0.3%, 0.5% or 0.6%, where the percentage is the percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In the raw material composition of the RTB-based permanent magnet material, the content of the Zr is, for example, 0.15%, 0.35%, 0.40%, or 0.50%, wherein the percentage is based on the total mass of the raw material composition of the RTB-based permanent magnet material percentage.

In the raw material composition of the RTB-based permanent magnet material, the Ga content is preferably 0.04-1.0%, such as 0.04%, 0.15%, 0.20%, 0.24%, 0.30%, 0.50%, 0.70% or 1.0%, The percentage is the percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In the raw material composition of the RTB-based permanent magnet material, the Ga content is preferably 0-0.21%, but not 0.21%, such as 0.04%, 0.15%, or 0.20%, wherein the percentage is the percentage of the RTB-based permanent magnet material. The percentage of the total mass of the raw material composition of the magnetic material.

In the raw material composition of the RTB-based permanent magnet material, the content of Ga is preferably 0.21-0.46%, such as 0.24% or 0.30%, wherein the percentage is based on the total mass of the raw material composition of the RTB-based permanent magnet material percentage.

In the raw material composition of the RTB-based permanent magnet material, the Ga content is preferably 0.46-1%, but not 0.46%, such as 0.50%, 0.70%, or 1.0%, where the percentage is the percentage of the RTB-based permanent magnet material. The percentage of the total mass of the raw material composition of the magnetic material.

In the raw material composition of the R-T-B permanent magnetic material, the content of Co is, for example, 0, 0.1% or 0.3%, where the percentage is the percentage of the total mass of the raw material composition of the R-T-B permanent magnetic material.

In the raw material composition of the RTB-based permanent magnet material, the content of B is, for example, 0.95%, 0.99%, 1.02%, or 1.05%, wherein the percentage is based on the total mass of the raw material composition of the RTB-based permanent magnet material percentage.

In the raw material composition of the R-T-B permanent magnet material, the type of M is preferably one or more of Al, Cu, Ti, Nb, and Hf.

In the raw material composition of the RTB-based permanent magnet material, the content of M is preferably 0-2%, such as 0, 0.1%, 0.15%, 0.16%, 0.58%, 0.6%, or 0.85%, where the percentage is The percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In the raw material composition of the RTB-based permanent magnet material, when the M contains Al, the content of Al is preferably 0-1% (excluding 0), such as 0.03%, 0.04% or 0.6%, where the percentage is It is a percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In the raw material composition of the RTB-based permanent magnetic material, when the M contains Cu, the content of Cu is preferably 0-0.55% (excluding 0), such as 0.05%, 0.10%, 0.12%, 0.15% Or 0.4%, where the percentage is the percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In the raw material composition of the RTB-based permanent magnet material, when the M contains Ti, the content of Ti is preferably 0.05-0.2%, for example, 0.05% or 0.15%, wherein the percentage is the percentage of the RTB-based permanent magnet The percentage of the total mass of the raw material composition of the material.

In the raw material composition of the RTB-based permanent magnet material, when the M contains Nb, the content of the Nb is preferably 0-0.2% (not including 0), for example, 0.05%, where the percentage is the percentage of the RTB-based permanent magnet material. The percentage of the total mass of the raw material composition of the permanent magnet material.

In the raw material composition of the RTB-based permanent magnet material, when the M contains Hf, the content of the Hf is preferably 0-0.2% (not including 0), for example, 0.1%, where the percentage is the percentage of the RTB-based permanent magnet material. The percentage of the total mass of the raw material composition of the permanent magnet material.

In a certain scheme, in the raw material composition of the R-T-B permanent magnet material, the definitions of certain components can be as follows, and the definitions of the remaining components are as described in any of the above schemes: the R does not contain Tb.

In a certain scheme, in the raw material composition of the RTB-based permanent magnet material, the definitions of some components can be as follows, and the definitions of the remaining components are as described in any of the above schemes: the R does not contain Dy and Tb Other heavy rare earth elements.

In a certain scheme, in the raw material composition of the R-T-B permanent magnet material, the definitions of some components can be as follows, and the definitions of other components are as described in any of the above schemes: the R does not contain Ho.

In a certain scheme, in the raw material composition of the RTB-based permanent magnet material, the definitions of certain components can be as follows, and the definitions of other components are as described in any of the above schemes: except for unavoidable impurities, The R does not contain rare earth metals other than Nd and Pr.

In a certain scheme, in the raw material composition of the R-T-B permanent magnet material, the definition of some components can be as follows, and the definition of the other components is as described in any of the above schemes: the content of Co is zero.

In a certain scheme, in the raw material composition of the RTB-based permanent magnet material, the definitions of certain components can be as follows, and the definitions of the remaining components are as described in any of the above schemes: the content of Co is 0- 0.3% (excluding 0), for example, the content of Co is 0.1% or 0.3%, where the percentage is the percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

In a certain scheme, in the raw material composition of the R-T-B permanent magnet material, the definitions of some components can be as follows, and the definitions of other components are as described in any of the above schemes:

The content of Ga is 0-0.05%, but not 0; the M is one or more of Al, Cu, Ti, Nb, and Hf; the percentage refers to the raw material of the RTB-based permanent magnet material The mass percentage of the total mass of the composition.

The R does not contain Tb; the Ga content is 0.05-0.2%, but not 0.2%; the M is one or more of Al, Cu, Ti, Nb, and Hf; the percentage refers to the total The mass percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

The content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Al is <0.05% or >0.5%; and Al+Cu ≥0.55%; the percentage refers to the mass percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

The R does not contain Tb; the Ga content is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the Al content is <0.05% or> 0.5%; and Al+Cu<0.55%; the percentage refers to the mass percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

The content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% or >0.2%; and Al+Cu ≥0.55%; the percentage refers to the mass percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

The R does not contain Tb; the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% or> 0.2%; and Al+Cu<0.55%; the percentage refers to the mass percentage of the total mass of the raw material composition of the RTB-based permanent magnet material.

The content of Ga is 0.2-0.25%; the content of Zr is 0.35-0.5%; the M is one or more of Al, Cu, Ti, Nb and Hf; the percentage refers to the percentage of the RTB It is the mass percentage of the total mass of the raw material composition of the permanent magnet material.

The content of Ga is 0.25-0.84%, but not 0.25%; wherein, when the content of Ga is 0.25-0.46%, the content of Zr is 0.34-0.5%; when the content of Ga is When 0.46-0.84% but not 0.46%, the content of Zr is 0.15-0.5%;

The M is one or more of Al, Cu, Ti, Nb and Hf; when the M contains Al, the content of Al is <0.05% or >0.5%; the percentage refers to the percentage of the RTB It is the mass percentage of the total mass of the raw material composition of the permanent magnet material.

The content of Ga is 0.85-1%; the M is one or more of Al, Cu, Ti, Nb and Hf; the percentage refers to the total mass of the raw material composition of the RTB-based permanent magnet material The mass percentage.

In a certain scheme, the raw material composition of the R-T-B permanent magnet material, in terms of mass percentage, contains the following components:

R, 29.5-32%, said R is a rare earth element containing at least Nd, and the content of Pr is 0-8%;

Zr, 0.15-0.50%;

Ga, 0.04-1%, and when the content of Ga is 0.21-0.46%, the content of Zr is 0.34-0.5%;

Co, 0-0.3%;

M, 0-3%, the M is one or more of Al, Cu, Ti, Nb and Hf;

B, 0.95-1.05%;

Fe, 64-70%;

In a certain scheme, the raw material composition of the RTB-based permanent magnetic material can be any one of the following numbers 1-13, wherein the percentage is each component accounting for the raw material composition of the RTB-based permanent magnetic material The mass percentage of the total mass, the sum of the content of each component is 100%,

"/" means that the element is not contained.

The present invention also provides a method for preparing the R-T-B series permanent magnet material, which can be achieved by subjecting the raw material composition of the R-T-B series permanent magnet material to smelting, powdering, molding, sintering and aging treatments.

In the preparation method of the RTB-based permanent magnet material, the smelting operation and conditions may be conventional smelting processes in the field. Generally, the raw material composition of the RTB-based permanent magnet material is made by ingot casting process and quick-setting flake process. Smelting and casting are performed to obtain alloy flakes.

Those skilled in the art know that because rare earth elements are usually lost in the smelting and sintering process, in order to ensure the quality of the final product, an additional 0-0.3wt% of rare earth elements ( Generally Nd element), the percentage is the weight percentage of the content of the additional rare earth element to the total content of the raw material composition; in addition, the content of this part of the additional rare earth element is not included in the category of the raw material composition.

In the preparation method of the R-T-B series permanent magnet material, the melting temperature may be 1300-1600°C.

In the preparation method of the R-T-B series permanent magnet material, the smelting equipment is generally a high frequency vacuum melting furnace and/or an intermediate frequency vacuum melting furnace. The intermediate frequency vacuum melting furnace is, for example, an intermediate frequency vacuum induction rapid-solidifying belt spinning furnace.

In the preparation method of the R-T-B series permanent magnetic material, the operation and conditions of the powder milling can be conventional powder milling processes in the field, and generally include hydrogen crushing powder milling and/or jet milling powder milling.

The hydrogen crushing and pulverizing generally includes hydrogen absorption, dehydrogenation and cooling treatment. The temperature of the hydrogen absorption is generally 20-200°C. The temperature of the dehydrogenation is generally 400-650°C. The pressure of the hydrogen absorption is generally 50-600 kPa.

The pressure of the pulverizing chamber of the jet mill is generally 0.1-2 MPa. The gas stream in the gas stream milling powder can be, for example, nitrogen gas and/or argon gas. The efficiency of the jet milling powder may vary according to different equipment, for example, it may be 30-400 kg/h, preferably 200 kg/h.

In the preparation method of the R-T-B series permanent magnet material, the molding operation and conditions can be conventional molding processes in the art. For example, the magnetic field forming method. The magnetic field strength of the magnetic field forming method is generally above 1.5T.

In the preparation method of the RTB-based permanent magnet material, the operation and conditions of the sintering treatment can be a conventional sintering process in the field, such as a vacuum sintering process and/or an inert atmosphere sintering process. The vacuum sintering process or the inert atmosphere sintering process are conventional operations in the art. When the inert atmosphere sintering process is used, the initial stage of sintering can be performed under the condition of a ^{vacuum degree of less than 5×10 -1 Pa.} The inert atmosphere may be an atmosphere containing inert gas conventional in the art, such as helium and argon.

In the preparation method of the R-T-B series permanent magnet material, the temperature of the sintering treatment may be 1000-1200°C, preferably 1030-1090°C.

In the preparation method of the R-T-B series permanent magnet material, the sintering treatment time may be 0.5-10h, preferably 2-8h.

In the preparation method of the R-T-B series permanent magnet material, the temperature of the aging treatment may be 450°C-600°C, for example, 480-510°C.

In the preparation method of the R-T-B series permanent magnetic material, the time of the aging treatment may be 1 to 4 hours, for example, 1 to 3 hours.

Wherein, preferably, after the sintering treatment and before the aging treatment, a grain boundary diffusion treatment is also performed.

Wherein, the grain boundary diffusion treatment can be processed according to a conventional process in the art, for example, the surface of the sintered body obtained by the sintering process is vapor-deposited, coated, or sputtered to attach a substance containing Tb and/or a substance containing Dy. Substances can be subjected to diffusion heat treatment.

In the grain boundary diffusion treatment, the Tb-containing substance may be Tb metal, Tb-containing compound (for example, Tb-containing fluoride), or alloy.

In the grain boundary diffusion treatment, the substance containing Dy may be Dy metal, a compound containing Dy (for example, a fluoride containing Dy), or an alloy.

In the grain boundary diffusion treatment, the temperature of the diffusion heat treatment may be 800-900°C, such as 850°C.

In the grain boundary diffusion treatment, the time of the diffusion heat treatment may be 12-48h, such as 24h.

In addition to the above-mentioned preparation method, the raw material composition of the above-mentioned R-T-B series permanent magnetic material can also be prepared by using a two-phase alloy process to prepare the R-T-B series permanent magnetic material. The two-phase alloy process can be conventional in the art.

The present invention also provides an R-T-B series permanent magnet material prepared by the above-mentioned preparation method.

The present invention also provides a R-T-B series permanent magnet material, which contains the following components in terms of mass percentage:

R, 29.5-32%, wherein the R is a rare earth element containing at least Nd, and the content of Pr is 0-17%;

Zr, 0.15-0.50%;

Co, 0-0.3%;

B, 0.95-1.05%;

Fe, 64-70%;

The percentage is the mass percentage of each component in the total mass of the R-T-B permanent magnet material, and the sum of the content of each component is 100%.

In the RTB-based permanent magnetic material, Ga and M basically do not enter the main phase, and are mainly distributed at the grain boundary, and will replace part of Fe in the grain boundary. By controlling the content of R, B, Zr, and Ga, an enriched phase is generated at the grain boundary. The enriched phase helps to optimize the grain boundary defects, thereby increasing the coercivity of the magnet, improving the squareness, and improving the high-temperature performance. At the same time, since no trace amount of Co content is added or controlled, Co will not be enriched in the grain boundaries, thereby inhibiting intergranular fracture and improving mechanical properties. The composition of the enriched phase is R _p -(Zr _x ,Ga _y ,M _z ) _q -Fe _100-pq , wherein: R is a rare earth element containing at least Nd; M is Al, Cu, Ti, Nb, Hf One or more of, Si, Sn, Ge, Ag, Au, Bi and Mn; p, q, x, y and z meet the following conditions: 16≤p≤28 (at%) (for example, 18.3); 5≤q≤16 (at%) (for example, 15.38); x/(y+z)=0.6 to 0.9 (for example, 0.7), and at% is an atomic percentage.

In the R-T-B series permanent magnet material, the R may be a rare earth element added in a smelting process and/or a diffusion process, for example, a rare earth element added in a smelting process.

In the R-T-B series permanent magnetic material, the content of R is, for example, 29.8%, 30.2%, 30.3%, 30.5% or 32%, wherein the percentage is a percentage of the total mass of the R-T-B series permanent magnetic material.

In the RTB-based permanent magnet material, the Nd content can be conventional in the art, preferably 21.9-30.1%, such as 21.9%, 22.3%, 22.7%, 22.8%, 23.6%, 23.8%, 23.9%, 29.6% Or 30.1%, where the percentage is the percentage of the total mass of the RTB-based permanent magnet material.

In the RTB-based permanent magnet material, the addition form of Nd in the R can be conventional in the art, for example, in the form of PrNd, or in the form of pure Nd, or in the form of a mixture of pure Pr and Nd , Or combined with a mixture of PrNd, pure Pr and Nd. When added in the form of PrNd, the mass ratio of Pr to Nd in PrNd is preferably 25:75, 20:80 or 10:90.

In the RTB-based permanent magnetic material, the content of Pr is preferably 0-10%, more preferably 0-8%, such as 0, 5.9%, 6%, 7.3%, 7.4%, 7.6% or 8.0%, The percentage is the percentage of the total mass of the RTB-based permanent magnet material.

In the RTB-based permanent magnetic material, when the R contains Pr, the addition form of Pr can be conventional in the art, for example, in the form of PrNd, or in the form of pure Pr, or in the form of pure Pr and Nd. In the form of a mixture of PrNd, or a combination of PrNd, pure Pr and Nd. When added in the form of PrNd, the mass ratio of Pr to Nd in PrNd is preferably 25:75, 20:80 or 10:90.

In the R-T-B-based permanent magnetic material, the R may further include a heavy rare earth element. The heavy rare earth element may be a heavy rare earth element added in a smelting process and/or a diffusion process. Preferably, the heavy rare earth element is a heavy rare earth element added in a smelting process.

In the R-T-B series permanent magnetic material, the type of the heavy rare earth element may be a conventional type of heavy rare earth in the art, such as one or more of Dy, Tb, Gd, and Ho.

In the RTB-based permanent magnet material, when the R contains heavy rare earth elements, the content of the heavy rare earth elements can be conventional in the art, preferably 0 to 7% (excluding 0), and more preferably 0.1-0.6 %, such as 0.1%, 0.2%, 0.3%, 0.5% or 0.6%, where the percentage is the percentage of the total mass of the RTB-based permanent magnet material.

In the R-T-B series permanent magnetic material, the content of Zr is, for example, 0.15%, 0.35%, 0.40% or 0.50%, wherein the percentage is a percentage of the total mass of the R-T-B series permanent magnetic material.

In the RTB-based permanent magnetic material, the Ga content is preferably 0.04-1.0%, such as 0.04%, 0.15%, 0.20%, 0.24%, 0.30%, 0.50%, 0.70% or 1.0%, where the percentage is The RTB is a percentage of the total mass of the permanent magnet material.

In the RTB-based permanent magnetic material, the Ga content is preferably 0-0.21%, but not 0.21%, such as 0.04%, 0.15%, or 0.20%, where the percentage is the total mass of the RTB-based permanent magnetic material Percentage.

In the R-T-B series permanent magnetic material, the Ga content is preferably 0.21-0.46%, such as 0.24% or 0.30%, where the percentage is the percentage of the total mass of the R-T-B series permanent magnetic material.

In the RTB-based permanent magnetic material, the Ga content is preferably 0.46-1%, but not 0.46%, such as 0.50%, 0.70%, or 1.0%, where the percentage is the total mass of the RTB-based permanent magnetic material Percentage.

In the R-T-B-based permanent magnetic material, the content of Co is, for example, 0, 0.1% or 0.3%, where the percentage is a percentage of the total mass of the R-T-B-based permanent magnetic material.

In the R-T-B series permanent magnetic material, the content of B is, for example, 0.95%, 0.99%, 1.02% or 1.05%, wherein the percentage is a percentage of the total mass of the R-T-B series permanent magnetic material.

In the R-T-B-based permanent magnetic material, the type of M is preferably one or more of Al, Cu, Ti, Nb, and Hf.

In the RTB-based permanent magnetic material, the content of M is preferably 0-2%, such as 0, 0.1%, 0.15%, 0.16%, 0.58%, 0.6%, or 0.85%, wherein the percentage is the percentage of the RTB-based permanent magnet material. Percentage of the total mass of the permanent magnet material.

In the RTB-based permanent magnetic material, when the M contains Al, the content of Al is preferably 0-1% (excluding 0), such as 0.03%, 0.04% or 0.6%, where the percentage is RTB is the percentage of the total mass of permanent magnet materials.

In the RTB-based permanent magnetic material, when the M contains Cu, the content of Cu is preferably 0-0.55% (excluding 0), such as 0.05%, 0.10%, 0.12%, 0.15% or 0.4%, The percentage is the percentage of the total mass of the RTB-based permanent magnet material.

In the RTB-based permanent magnetic material, when the M contains Ti, the content of Ti is preferably 0.05-0.2% (not including 0), such as 0.05% or 0.15%, where the percentage is the percentage of the RTB-based permanent magnet material. The percentage of the total mass of the magnetic material.

In the RTB-based permanent magnetic material, when the M contains Nb, the Nb content is preferably 0-0.2% (not including 0), for example, 0.05%, where the percentage is the total of the RTB-based permanent magnetic material Percentage of quality.

In the RTB-based permanent magnetic material, when the M contains Hf, the Hf content is preferably 0-0.2% (not including 0), such as 0.1%, where the percentage is the total of the RTB-based permanent magnetic material Percentage of quality.

In a certain scheme, in the R-T-B series permanent magnet material, the definitions of some components can be as follows, and the definitions of other components are as described in any of the above schemes: the R does not contain Tb.

In a certain scheme, in the RTB-based permanent magnet material, the definitions of certain components can be as follows, and the definitions of other components are as described in any of the above schemes: the R does not contain heavy rare earths other than Dy and Tb element.

In a certain scheme, in the R-T-B-based permanent magnetic material, the definitions of certain components can be as follows, and the definitions of other components are as described in any of the above schemes: the R does not contain Ho.

In a certain scheme, in the RTB-based permanent magnetic material, the definitions of certain components can be as follows, and the definitions of other components are as described in any of the above schemes: Except for unavoidable impurities, the R does not contain Rare earth metals other than Nd and Pr.

In a certain scheme, in the R-T-B series permanent magnetic material, the definition of some components can be as follows, and the definition of the other components is as described in any of the above schemes: the content of Co is zero.

In a certain scheme, in the RTB-based permanent magnetic material, the definition of certain components can be as follows, and the definition of the remaining components is as described in any of the above schemes: the content of Co is 0-0.3% (not Contains 0), such as 0.1% or 0.3%, where the percentage is the percentage of the total mass of the RTB-based permanent magnet material.

In a certain scheme, in the R-T-B series permanent magnetic material, the definition of some components can be as follows, and the definition of other components is as described in any of the above schemes:

The content of Ga is 0-0.05%, but not 0; the M is one or more of Al, Cu, Ti, Nb, and Hf; the percentage refers to the total mass of the RTB-based permanent magnet material The percentage of mass.

The R does not contain Tb; the Ga content is 0.05-0.2%, but not 0.2%; the M is one or more of Al, Cu, Ti, Nb, and Hf; the percentage refers to the total The RTB is the mass percentage of the total mass of permanent magnet materials.

The content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Al is <0.05% or >0.5%; and Al+Cu ≥0.55%; percentage refers to the mass percentage of the total mass of the RTB-based permanent magnet material.

The R does not contain Tb; the Ga content is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the Al content is <0.05% or> 0.5%; and Al+Cu<0.55%; the percentage refers to the mass percentage of the total mass of the RTB-based permanent magnet material.

The content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% or >0.2%; and Al+Cu ≥0.55%; percentage refers to the mass percentage of the total mass of the RTB-based permanent magnet material.

The R does not contain Tb; the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% or> 0.2%; and Al+Cu<0.55%; the percentage refers to the mass percentage of the total mass of the RTB-based permanent magnet material.

The content of Ga is 0.2-0.25%; the content of Zr is 0.35-0.5%; the M is one or more of Al, Cu, Ti, Nb and Hf; the percentage refers to the percentage of the RTB It is the mass percentage of the total mass of the permanent magnet material.

The M is one or more of Al, Cu, Ti, Nb and Hf; when the M contains Al, the content of Al is <0.05% or >0.5%; the percentage refers to the percentage of the RTB It is the mass percentage of the total mass of the permanent magnet material.

The content of Ga is 0.85-1%; the M is one or more of Al, Cu, Ti, Nb, and Hf; and the percentage refers to the mass percentage of the total mass of the R-T-B permanent magnet material.

In a certain scheme, the R-T-B series permanent magnet material, in terms of mass percentage, contains the following components:

Zr, 0.15-0.50%;

Co, 0-0.3%;

M, 0-3%, the M is one or more of Al, Cu, Ti, Nb and Hf;

B, 0.95-1.05%;

Fe, 64-70%;

In a certain solution, the RTB-based permanent magnetic material can be any one of the following numbers 1-15, wherein the percentage is the mass percentage of each component in the total mass of the RTB-based permanent magnetic material, and each group The sum of the sub-content is 100%,

"/" means that the element is not contained.

The present invention also provides an application of the above-mentioned R-T-B series permanent magnetic material as an electronic component.

In the present invention, carbon impurities are generally unavoidably introduced in the preparation process, and the amount is generally 0-0.15%. The above-mentioned percentage is the mass percentage of the amount of C element in the total amount.

In the present invention, unless otherwise specified, the "percentage" involved refers to mass percentage.

On the basis of not violating common knowledge in the field, the above-mentioned preferred conditions can be combined arbitrarily to obtain preferred examples of the present invention.

The reagents and raw materials used in the present invention are all commercially available.

The positive progress effect of the present invention lies in: controlling the content of Ga and Zr elements at the same time, and there is a Zr-rich R _p -(Zr _x ,Ga _y ,M _z ) _q -Fe _100-pq enriched phase at the grain boundary. The phase helps high-temperature sintering and refines the grain structure, thereby increasing the coercivity of the magnet (H _cj ≥15.2kOe), improving the squareness (H _k /H _cj ≥0.98), and improving the high-temperature performance (Hcj temperature at 80℃) The absolute value of the coefficient ≤ 0.741; the absolute value of the Hcj temperature coefficient at 150 ℃ ≤ 0.451). At the same time, since the content of trace Co is not added or controlled, Co will not be enriched in the grain boundaries, thereby inhibiting intergranular fracture and improving the mechanical properties (flexural strength ≥462MPa).

Description of the drawings

FIG. 1 is the FE-EPMA spectrum of the R-T-B series permanent magnetic material prepared in Example 3.

detailed description

The present invention will be further explained in the following examples, but the present invention is not limited to the scope of the described examples. The experimental methods without specific conditions in the following examples are selected in accordance with conventional methods and conditions, or in accordance with the product specification.

1. The raw material composition of R-T-B series permanent magnet materials

The formulations of the raw material composition of the R-T-B permanent magnetic materials in Examples 1-13 and Comparative Examples 1-5 are shown in Table 1.

Table 1 Component and content (%) of the formula of the raw material composition of the R-T-B permanent magnetic material in Examples 1-13 and Comparative Examples 1-5

Note: "/" means that the element is not contained.

The preparation methods of the R-T-B series permanent magnet materials in Examples 1-13 and Comparative Examples 1-5 are as follows:

(1) Melting and casting process: According to the formula in Table 1, put the prepared raw materials into an alumina crucible, and conduct vacuum melting in a high-frequency vacuum melting furnace with a vacuum of 0.05 Pa and a condition of 1500°C. Then, argon gas is introduced into the intermediate frequency vacuum induction rapid-solidification belt spinning furnace to perform casting, and then the alloy is quenched to obtain alloy flakes.

(2) Hydrogen crushing process: vacuum the hydrogen crushing furnace containing the quench alloy at room temperature, and then pass hydrogen with a purity of 99.9% into the hydrogen crushing furnace, maintain the hydrogen pressure at 90kPa, and fully absorb hydrogen , The temperature is raised while vacuuming, and the hydrogen is fully dehydrogenated, and then cooled, and the powder after the hydrogen breakage is taken out. Among them, the temperature for hydrogen absorption is room temperature, and the temperature for dehydrogenation is 550°C.

(3) Airflow milling process: Under the nitrogen atmosphere, the hydrogen crushed powder is pulverized by airflow under the condition of 0.65MPa in the crushing chamber (the efficiency of airflow milling may vary depending on the equipment. For example, it can be 200kg/h) to obtain fine powder.

(4) Molding process: The powder after jet milling is pressed into a shape in a magnetic field strength above 1.5T.

(5) Sintering process: each molded body is moved to a sintering furnace for sintering, sintered under a vacuum of less than 0.5 Pa, and sintered at 1030-1090°C for 2-8 hours to obtain a sintered body.

(6) Aging treatment process: the sintered body is heated from 20°C to 500°C at a heating rate of 3-5°C/min in high-purity Ar, heat-treated at 500°C for 3 hours, then cooled to room temperature and taken out.

Example 14

The sintered body obtained by the sintering treatment in Example 3 was first subjected to the grain boundary diffusion treatment and then to the aging treatment. The remaining steps are the same as in Example 3. The grain boundary diffusion treatment process is as follows:

The sintered body is processed into a magnet with a thickness of 20mm×20mm and a sheet thickness of less than 7mm. The thickness direction is the direction of the magnetic field orientation. After the surface is cleaned, raw materials prepared from Dy fluoride are used to spray the magnet on the entire surface. After the magnet is dried, it is then subjected to diffusion heat treatment at a temperature of 850°C for 24 hours in a high-purity Ar atmosphere. Cool to room temperature.

Example 15

The sintered body obtained by sintering in Example 1 was firstly subjected to grain boundary diffusion treatment, and then subjected to aging treatment. The remaining steps are the same as in Example 1. The grain boundary diffusion treatment process is as follows:

The sintered body is processed into a magnet with a thickness of 20mm×20mm and a sheet thickness of less than 7mm. The thickness direction is the direction of the magnetic field orientation. After the surface is cleaned, the raw materials made of Tb fluoride are used to spray and coat the magnet on the entire surface. After the magnet is dried, it is then subjected to diffusion heat treatment at a temperature of 850°C for 24 hours in a high-purity Ar atmosphere. Cool to room temperature.

Effect Example 1

Take the R-T-B permanent magnetic materials in Examples 1-15 and Comparative Examples 1-5, measure their magnetic properties and composition, and observe the microstructure of their magnets.

(1) Each component of the R-T-B series permanent magnetic material is measured using a high-frequency inductively coupled plasma emission spectrometer (ICP-OES, instrument model: Icap6300). Table 2 below shows the component test results. Taking Example 1 as an example, the types and amounts of elements detected from the R-T-B permanent magnet material are the same as those of the raw material composition disclosed in Table 1.

Table 2 Composition and content (%) of R-T-B series permanent magnetic materials in Examples 1-15 and Comparative Examples 1-5

Note: "/" means that the element is not contained.

(2) Magnetic performance evaluation: RTB series permanent magnet materials use the NIM-10000H BH bulk rare earth permanent magnet non-destructive measurement system of China Metrology Institute for magnetic performance testing (the test sample is a disc with diameter D10mm×thickness 5mm); magnetic performance testing The results are shown in Table 3.

Mechanical performance evaluation: R-T-B series permanent magnet material universal testing machine is used to test the bending strength. The size of the test sample is 20mm×7.5mm×6.5mm, and 6.5mm is the orientation direction.

table 3

(3) Measurement of microstructure: Polish the vertical orientation surface of the R-T-B permanent magnetic material, and use a field emission electron probe microanalyzer (FE-EPMA) (JEOL, 8530F) to detect it. Firstly, the distribution of Nd, Zr, Ga and other elements in the permanent magnetic material is determined by scanning the FE-EPMA surface. Then through FE-EPMA single-point quantitative analysis to determine the content of elements such as Nd, Zr, Ga, etc., the test conditions are accelerating voltage of 15kv, probe beam current of 50nA.

The RTB-based permanent magnet material prepared in Example 3 was subjected to FE-EPMA test, and the results are shown in Fig. 1 and Table 4. Among them, Figure 1 respectively corresponds to the concentration distribution diagrams of Nd, Ga, and Zr. It can be seen from Figure 1 that there is a Zr-rich phase at the grain boundary, and the content of Ga in the Zr-rich phase is higher than its content in the main phase. The position of arrow 1 in Fig. 1 is the main phase, and the arrow 2 in Fig. 1 is the Zr-rich phase. It can be seen from Table 4 that in the Zr-rich phase, the amount of rare earth is about 18.3 at%, and the ratio of Zr to Ga is 0.7. Similarly, the FE-EPMA detection of other examples shows that there is an R _p -(Zr _x ,Ga _y ,M _z ) _q -Fe _100-pq enriched phase at the grain boundary, 16≤p≤28( at%); 5≤q≤16(at%); x/(y+z)=0.6～0.9. (at% refers to atomic percentage).

Table 4

In Table 4, the content of each element refers to atomic percentage (at%).

The specific embodiments and comparative examples are analyzed as follows:

(1) In the present invention, the contents of Ga and Zr are simultaneously controlled, and the obtained RTB permanent magnet material has excellent magnetic properties: B _r ≥14.28kGs, H _cj ≥15.2kOe; H _k /H _cj ≥0.98; Hcj temperature at 80°C The absolute value of the coefficient is ≤0.741; the absolute value of the Hcj temperature coefficient is ≤0.451 at 150℃. Excellent mechanical properties: bending strength ≥462MPa (Examples 1-15).

(2) Based on the formula of the present invention, changes in the amount of raw materials Zr, B, Co or Pr, the magnetic properties and mechanical properties of RTB permanent magnet materials are significantly reduced, especially H _cj , the absolute value of the temperature coefficient of Hcj at 80 ℃ and the bending resistance Strength (comparative examples 1-4);

(3) In the process of research, the inventor found that by controlling the content of Ga and Zr elements at the same time, R _p -(Zr _x ,Ga _y ,M _z ) _q -Fe _100-pq rich in Zr can exist at the grain boundary. Collecting phases, this phase helps high-temperature sintering and refines the grain structure, thereby enhancing the coercivity of the magnet, improving the squareness, and improving the high-temperature performance. At the same time, since no trace amount of Co content is added or controlled, Co will not be enriched in the grain boundaries, thereby inhibiting intergranular fracture and improving mechanical properties.

Claims

A raw material composition of R-T-B series permanent magnet material, characterized in that, in terms of mass percentage, it contains the following components:

R, 29.5-32%, said R is a rare earth element containing at least Nd, and the content of Pr is 0-17%;

Zr, 0.15-0.50%;

Ga, 0-1%, but not 0, and when the content of Ga is 0.21-0.46%, the content of Zr is 0.34-0.5%;

Co, 0-0.3%;

M, 0-3%, the M is one or more of Al, Cu, Ti, Nb, Hf, Si, Sn, Ge, Ag, Au, Bi and Mn;

B, 0.95-1.05%;

Fe, 64-70%;

The percentage is the mass percentage of each component in the total mass of the raw material composition of the R-T-B permanent magnet material, and the sum of the content of each component is 100%.
The raw material composition of the R-T-B series permanent magnet material according to claim 1, wherein said R is a rare earth element added in a smelting process and/or a diffusion process; for example, a rare earth element added in a smelting process;

And/or, the content of R is 29.8%, 30.2%, 30.3%, 30.5% or 32%;

And/or, the Nd content is 21.9-30.1%, such as 21.9%, 22.3%, 22.7%, 22.8%, 23.6%, 23.8%, 23.9%, 29.6% or 30.1%;

And/or, the content of Pr is 0-10%, preferably 0-8%, such as 0, 5.9%, 6%, 7.3%, 7.4%, 7.6% or 8.0%;

And/or, said R also contains heavy rare earth elements; wherein:

Preferably, the heavy rare earth element is a heavy rare earth element added in a smelting process and/or a diffusion process, and more preferably, the heavy rare earth element is a heavy rare earth element added in a smelting process;

Preferably, the heavy rare earth element is one or more of Dy, Tb, Gd and Ho;

Preferably, the content of the heavy rare earth element is 0-7%, but does not contain 0, preferably 0.1-0.6%, such as 0.1%, 0.2%, 0.3%, 0.5% or 0.6%;

And/or, the content of Zr is 0.15%, 0.35%, 0.40% or 0.50%;

And/or, the Ga content is 0.04-1.0%, such as 0.04%, 0.15%, 0.20%, 0.24%, 0.30%, 0.50%, 0.70% or 1.0%;

And/or, the content of Ga is 0-0.21%, but not 0.21%, such as 0.04%, 0.15% or 0.20%;

And/or, the content of Ga is 0.21-0.46%, such as 0.24% or 0.30%;

And/or, the content of Ga is 0.46%-1%, but not 0.46%, such as 0.50%, 0.70% or 1.0%;

And/or, the content of Co is 0, 0.1% or 0.3%;

And/or, the content of B is 0.95%, 0.99%, 1.02% or 1.05%;

And/or, the M is one or more of Al, Cu, Ti, Nb and Hf;

And/or, the content of M is 0-2%, for example, 0, 0.1%, 0.15%, 0.16%, 0.58%, 0.6% or 0.85%;

And/or, when the M contains Al, the content of Al is 0-1%, but does not contain 0, such as 0.03%, 0.04% or 0.6%;

And/or, when the M contains Cu, the content of Cu is 0-0.55%, but does not contain 0, such as 0.05%, 0.10%, 0.12%, 0.15% or 0.4%;

And/or, when the M contains Ti, the content of Ti is 0.05-0.2%, for example, 0.05% or 0.15%;

And/or, when the M contains Nb, the content of Nb is 0-0.2%, but does not contain 0, for example, 0.05%;

And/or, when the M contains Hf, the content of the Hf is 0-0.2%, but does not contain 0, for example, 0.1%.
The raw material composition of the R-T-B series permanent magnetic material according to claim 1 or 2, wherein the R does not contain Tb;

Alternatively, the R does not contain heavy rare earth elements other than Dy and Tb;

Or, the R does not include Ho;

Or, except for unavoidable impurities, the R does not contain rare earth metals other than Nd and Pr;

Or, the content of Co is 0;

Alternatively, the content of Co is 0-0.3%, but does not contain 0; for example, the content of Co is 0.1% or 0.3%;

Alternatively, the content of Ga is 0-0.05%, but not 0; the M is one or more of Al, Cu, Ti, Nb, and Hf;

Alternatively, the R does not contain Tb; the content of Ga is 0.05-0.2%, but not 0.2%; and the M is one or more of Al, Cu, Ti, Nb, and Hf;

Alternatively, the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb, and Hf; the content of Al is <0.05% or >0.5%; and Al +Cu≥0.55%;

Alternatively, the R does not contain Tb; the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Al is <0.05% Or>0.5%; and Al+Cu<0.55%;

Alternatively, the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% or >0.2%; and Al +Cu≥0.55%;

Alternatively, the R does not contain Tb; the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% Or>0.2%; and Al+Cu<0.55%;

Alternatively, the content of Ga is 0.2-0.25%; the content of Zr is 0.35-0.5%; and the M is one or more of Al, Cu, Ti, Nb, and Hf;

Or, the content of Ga is 0.25-0.84% but not 0.25%; wherein, when the content of Ga is 0.25-0.46%, the content of Zr is 0.34-0.5%; when the content of Ga When the content is 0.46-0.84% but not 0.46%, the content of the Zr is 0.15-0.5%;

The M is one or more of Al, Cu, Ti, Nb and Hf; when the M contains Al, the content of Al is <0.05% or >0.5%;

Alternatively, the content of Ga is 0.85-1%; the M is one or more of Al, Cu, Ti, Nb and Hf;

Alternatively, the raw material composition of the RTB-based permanent magnet material, in terms of mass percentage, contains the following components: R, 29.5-32%, the R is a rare earth element containing at least Nd, and the content of Pr is 0-8%; Zr, 0.15-0.50%; Ga, 0.04-1%, and when the content of Ga is 0.21-0.46%, the content of Zr is 0.34-0.5%; Co, 0-0.3%; M, 0 -3%, the M is one or more of Al, Cu, Ti, Nb and Hf; B, 0.95-1.05%; Fe, 64-70%; the percentage is that each component accounts for the permanent The mass percentage of the total mass of the raw material composition of the magnetic material, and the sum of the content of each component is 100%;

Alternatively, the raw material composition of the RTB-based permanent magnet material is any one of the following numbers 1-13, wherein the percentage is the mass percentage of each component in the total mass of the raw material composition of the RTB-based permanent magnet material , The sum of the content of each component is 100%,

"/" means that the element is not contained.
A method for preparing an RTB-based permanent magnet material, characterized in that the raw material composition of the RTB-based permanent magnet material according to any one of claims 1 to 3 is subjected to smelting, powdering, molding, sintering and aging treatments , You can.
The method for preparing an RTB-based permanent magnet material according to claim 4, wherein the smelting comprises the following steps: the raw material composition of the RTB-based permanent magnet material is smelted and casted by an ingot casting process and a quick-setting sheet process , Get the alloy sheet;

And/or, the smelting temperature is 1300-1600°C;

And/or, the smelting equipment is a high frequency vacuum melting furnace and/or an intermediate frequency vacuum melting furnace;

And/or, the pulverizing includes hydrogen crushing pulverizing and/or jet milling pulverizing;

Wherein, the hydrogen pulverizing powder preferably includes hydrogen absorption, dehydrogenation and cooling treatment; the temperature of hydrogen absorption is preferably 20 to 200°C; the temperature of dehydrogenation is preferably 400 to 650°C ; The pressure of the hydrogen absorption is preferably 50 ~ 600kPa;

The pressure of the airflow milling and grinding chamber is preferably 0.1-2 MPa; the airflow in the airflow milling powder is preferably nitrogen and/or argon; the efficiency of the airflow grinding powder is preferably 30 -400kg/h, such as 200kg/h;

And/or, the molding is a magnetic field molding method, and the magnetic field strength of the magnetic field molding method is preferably above 1.5T;

And/or, the sintering process is a vacuum sintering process and/or an inert atmosphere sintering process;

Wherein, when the inert atmosphere sintering process is adopted, the initial stage of sintering can be carried out under the condition that the vacuum degree is lower than 5×10 -1 Pa; the inert atmosphere is preferably helium or argon;

And/or, the temperature of the sintering treatment is 1000-1200°C, preferably 1030-1090°C;

And/or, the sintering treatment time is 0.5-10h, preferably 2-8h;

And/or, the temperature of the aging treatment is 450°C-600°C, such as 480-510°C;

And/or, the time of the aging treatment may be 1 to 4 hours, for example, 1 to 3 hours;

And/or, after the sintering treatment and before the aging treatment, a grain boundary diffusion treatment is further performed;

When the grain boundary diffusion treatment is performed, the grain boundary diffusion treatment preferably includes the following steps: vapor-depositing, coating or sputtering on the surface of the sintered body obtained by the sintering treatment to attach a substance containing Tb and/or containing Dy The substance that contains Dy can be subjected to diffusion heat treatment; the substance containing Tb can be Tb metal, a compound containing Tb (such as fluoride containing Tb) or an alloy; the substance containing Dy can be Dy metal or Dy-containing Compound (for example, fluoride containing Dy) or alloy; the temperature of the diffusion heat treatment may be 800-900°C, such as 850°C; the time of the diffusion heat treatment may be 12-48h, such as 24h.
An R-T-B series permanent magnet material prepared by the preparation method according to claim 4 or 5.
An RTB-based permanent magnet material, characterized in that, in terms of mass percentage, it contains the following components: R, 29.5-32%, wherein the R is a rare earth element containing at least Nd, and the content of Pr is 0-17%;

Zr, 0.15-0.50%;

Ga, 0-1%, but not 0, and when the content of Ga is 0.21-0.46%, the content of Zr is 0.34-0.5%;

Co, 0-0.3%;

M, 0-3%, the M is one or more of Al, Cu, Ti, Nb, Hf, Si, Sn, Ge, Ag, Au, Bi and Mn;

B, 0.95-1.05%;

Fe, 64-70%;

The percentage is the mass percentage of each component in the total mass of the R-T-B permanent magnet material, and the sum of the content of each component is 100%.
The RTB-based permanent magnetic material of claim 7, wherein the composition of the RTB-based permanent magnetic material at the grain boundary is R p -(Zr x ,Ga y ,M z ) q -Fe 100-pq P , Q, x, y and z meet the following conditions: 16≤p≤28(at%) (for example, 18.3); 5≤q≤16(at%) (for example, 15.38); x/(y+z)=0.6 ～0.9 (for example 0.7), at% is atomic percentage;

And/or, the R is a rare earth element added in a smelting process and/or a diffusion process, for example, a rare earth element added in a smelting process;

And/or, the content of R is 29.8%, 30.2%, 30.3%, 30.5% or 32%;

And/or, the Nd content is 21.9-30.1%, such as 21.9%, 22.3%, 22.7%, 22.8%, 23.6%, 23.8%, 23.9%, 29.6% or 30.1%;

And/or, the content of Pr is 0-10%, preferably 0-8%, such as 0, 5.9%, 6%, 7.3%, 7.4%, 7.6% or 8.0%;

And/or, said R also contains heavy rare earth elements;

When the R further contains a heavy rare earth element, the heavy rare earth element may be a heavy rare earth element added in a smelting process and/or a diffusion process, preferably, the heavy rare earth element is a heavy rare earth element added in a smelting process ；

When the R further contains a heavy rare earth element, the heavy rare earth element may be one or more of Dy, Tb, Gd, and Ho;

When the R further contains a heavy rare earth element, the content of the heavy rare earth element may be 0-7%, but does not contain 0, preferably 0.1-0.6%, such as 0.1%, 0.2%, 0.3%, 0.5% or 0.6%;

And/or, the content of Zr is 0.15%, 0.35%, 0.40% or 0.50%;

And/or, the Ga content is 0.04-1.0%, such as 0.04%, 0.15%, 0.20%, 0.24%, 0.30%, 0.50%, 0.70% or 1.0%;

And/or, the content of Ga is 0-0.21%, but not 0.21%, such as 0.04%, 0.15% or 0.20%;

And/or, the content of Ga is 0.21-0.46%, such as 0.24% or 0.30%;

And/or, the content of Ga is 0.46%-1%, but not 0.46%, such as 0.50%, 0.70% or 1.0%;

And/or, the content of Co is 0, 0.1% or 0.3%;

And/or, the content of B is 0.95%, 0.99%, 1.02% or 1.05%;

And/or, the M is one or more of Al, Cu, Ti, Nb and Hf;

And/or, the content of M is 0-2%, for example, 0, 0.1%, 0.15%, 0.16%, 0.58%, 0.6% or 0.85%;

And/or, when the M contains Al, the content of Al is 0-1%, but does not contain 0, such as 0.03%, 0.04% or 0.6%;

And/or, when the M contains Cu, the content of Cu is 0-0.55%, but does not contain 0, such as 0.05%, 0.10%, 0.12%, 0.15% or 0.4%;

And/or, when the M contains Ti, the content of Ti is 0.05-0.2%, for example, 0.05% or 0.15%;

And/or, when the M contains Nb, the content of Nb is 0-0.2%, but does not contain 0, for example, 0.05%;

And/or, when the M contains Hf, the content of the Hf is 0-0.2%, but does not contain 0, for example, 0.1%.
The R-T-B series permanent magnetic material according to claim 7 or 8, wherein said R does not contain Tb;

Or, the R does not contain heavy rare earth elements other than Dy and Tb

Or, the R does not include Ho;

Or, except for unavoidable impurities, the R does not contain rare earth metals other than Nd and Pr;

Or, the content of Co is 0;

Alternatively, the content of Co is 0-0.3%, but does not contain 0; for example, the content of Co is 0.1% or 0.3%;

Alternatively, the content of Ga is 0-0.05%, but not 0; the M is one or more of Al, Cu, Ti, Nb, and Hf;

Alternatively, the R does not contain Tb; the content of Ga is 0.05-0.2%, but not 0.2%; and the M is one or more of Al, Cu, Ti, Nb, and Hf;

Alternatively, the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb, and Hf; the content of Al is <0.05% or >0.5%; and Al +Cu≥0.55%;

Alternatively, the R does not contain Tb; the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Al is <0.05% Or>0.5%; and Al+Cu<0.55%;

Alternatively, the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% or >0.2%; and Al +Cu≥0.55%;

Alternatively, the R does not contain Tb; the content of Ga is 0.2-0.25%; the M is one or more of Al, Cu, Ti, Nb and Hf; the content of Cu is <0.07% Or>0.2%; and Al+Cu<0.55%;

Alternatively, the content of Ga is 0.2-0.25%; the content of Zr is 0.35-0.5%; and the M is one or more of Al, Cu, Ti, Nb, and Hf;

Or, the content of Ga is 0.25-0.84% but not 0.25%; wherein, when the content of Ga is 0.25-0.46%, the content of Zr is 0.34-0.5%; when the content of Ga When the content is 0.46-0.84% but not 0.46%, the content of the Zr is 0.15-0.5%; the M is one or more of Al, Cu, Ti, Nb and Hf; when the M When Al is included, the content of Al is <0.05% or >0.5%;

Alternatively, the content of Ga is 0.85-1%; the M is one or more of Al, Cu, Ti, Nb and Hf;

Or, R, 29.5-32%, the R is a rare earth element containing at least Nd, and the content of Pr is 0-8%; Zr, 0.15-0.50%; Ga, 0.04-1%, and when the content of Ga When it is 0.21-0.46%, the content of Zr is 0.34-0.5%; Co, 0-0.3%; M, 0-3%, the M is one or more of Al, Cu, Ti, Nb and Hf B, 0.95-1.05%; Fe, 64-70%; The percentage is the mass percentage of each component in the total mass of the RTB-based permanent magnet material, and the sum of the content of each component is 100%;

Alternatively, the RTB-based permanent magnet material is any one of the following numbers 1-15, wherein the percentage is the mass percentage of each component in the total mass of the RTB-based permanent magnet material, and the sum of the content of each component is 100%,

"/" means that the element is not contained.
An application of the R-T-B series permanent magnet material according to any one of claims 6-9 as an electronic component.