CN111599565B - Neodymium-iron-boron magnet material, raw material composition, preparation method and application thereof - Google Patents

Abstract

The invention discloses a neodymium iron boron magnet material, a raw material composition, a preparation method and application thereof. The raw material composition of the neodymium iron boron magnet material comprises: a first component: a light rare earth element (LR), the LR including Nd; ho, 0-10 mas%, and not 0; 0.35-0.6 mas% of Cu; c, 0-0.32 mas%; ga, 0-0.42 mas%, and is not 0; 0-0.5 mas% of Co; 0-0.5 mas% of Al; x, 0.05-0.5 mas%; b, 0.9-1.05 mas%; the balance being Fe; the first component does not comprise other heavy rare earth elements except Ho; a second component: dy and/or Tb, 0.2-1 mas%. The neodymium iron boron magnet material has good grain boundary continuity, high remanence, high coercivity, good high-temperature performance and good corrosion resistance.

Description

Neodymium-iron-boron magnet material, raw material composition, preparation method and application thereof

Technical Field

The invention relates to a neodymium iron boron magnet material, a raw material composition, a preparation method and application thereof.

Background

The Nd-Fe-B permanent magnet material takes an Nd2Fel4B compound as a matrix, has the advantages of high magnetic performance, small thermal expansion coefficient, easy processing, low price and the like, is increased at the speed of 20-30% per year on average since the coming of the world, and becomes the permanent magnet material with the most wide application. According to the preparation method, the Nd-Fe-B permanent magnet can be divided into three types of sintering, bonding and hot pressing, wherein the sintered magnet accounts for more than 80% of the total production and is most widely applied.

With the continuous optimization of the preparation process and the magnet components, the maximum magnetic energy product of the sintered Nd-Fe-B magnet is close to the theoretical value. With the rapid development of new industries such as wind power generation, hybrid electric vehicles, variable frequency air conditioners and the like in recent years, the demand of high-performance Nd-Fe-B magnets is more and more increased, and meanwhile, the application in the high-temperature field also puts higher requirements on the high-temperature performance of sintered Nd-Fe-B magnets.

In the prior art, Co is the most used and effective element when manufacturing heat-resistant and corrosion-resistant sintered Nd-Fe-B magnets. This is because the addition of Co can reduce the temperature coefficient of the reversible temperature coefficient of magnetic induction, effectively increase the curie temperature, and can improve the corrosion resistance of NdFeB magnets. However, the addition of Co easily causes a decrease in coercive force, and the cost of Co is high. The Al element can reduce the wetting angle between the main phase and the surrounding liquid phase during sintering, and improve the coercivity by improving the microstructure between the main phase and the Nd-rich phase, and therefore, the coercivity reduction caused by Co addition is also usually compensated by Al addition in the prior art. However, excessive addition of Al deteriorates the remanence and Curie temperature.

Disclosure of Invention

The invention provides a neodymium iron boron magnet material, a raw material composition, a preparation method and application thereof, aiming at overcoming the defects that the Curie temperature and the corrosion resistance of a neodymium iron boron magnet in the prior art are improved by adding Co, the Co is easy to cause rapid decrease of coercive force and high price, and the excessive addition of Al deteriorates the remanence and the Curie temperature. The neodymium iron boron magnet material has good grain boundary continuity, high remanence, high coercivity, good high-temperature performance and good corrosion resistance.

In order to achieve the purpose, the invention adopts the following technical scheme:

a raw material composition of a neodymium iron boron magnet material comprises a first component and a second component, wherein the first component is an element added during smelting, and the second component is an element added during grain boundary diffusion;

the first component includes:

a light rare earth element (LR), the LR including Nd;

ho, 0-10 mas%, and not 0;

Cu，0.35～0.6mas％；

C，0～0.32mas％；

ga, 0-0.42 mas%, and is not 0;

Co，0～0.5mas％；

Al，0～0.5mas％；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9～1.05mas％；

the balance being Fe;

the first component does not include other heavy rare earth elements except Ho;

the second component includes: dy and/or Tb 0.2-1 mas%;

and mas% is the mass percentage of each element in the raw material composition of the neodymium iron boron magnet material.

In the present invention, the content of Nd is preferably 16 to 27mas%, for example, 16.2, 21, 21.4, 24, 25.8, 26 or 26.5 mas%.

In the present invention, the LR may also include other light rare earth elements conventional in the art, including, for example, Pr and/or Sm. When the LR contains Pr, the content of the Pr can be 0-16 mas percent and is not 0; preferably 3-7, such as 5, mas%. The Pr can be added in the form of pure Pr and/or PrNd, preferably PrNd. The PrNd is an alloy of Pr and Nd, and the mass ratio of Pr to Nd in the PrNd is generally 25:75 or 20: 80. when the LR contains Sm, the content of the Sm can be 0-5 mas percent and is not 0; for example 2.5 mas%.

In the present invention, the content of Ho is preferably 0.5 to 8mas%, for example, 1, 2, 4, 4.5 or 6 mas%.

In the present invention, the content range of Cu is preferably 0.4 to 0.55mas%, for example, 0.45, 0.5 or 0.52 mas%.

In the present invention, the content range of C is preferably 0.07 to 0.2mas%, for example, 0.098, 0.12, 0.15 or 0.16 mas%. When the content of C is 0 to 0.12mas%, C may be an impurity C introduced in the process of preparing the neodymium iron boron material, for example, a lubricant and the like are generally added in the preparation process to introduce the C impurity.

In the present invention, the content of Ga is preferably in the range of 0.06 to 0.3mas%, for example, 0.07, 0.09, or 0.15 mas%.

In the present invention, the content of Al is preferably 0 to 0.3mas%, more preferably 0 to 0.1mas%, such as 0.01, 0.02, 0.04, or 0.05 mas%. When the content of Al is 0-0.1 mas%, the Al can be impurity Al introduced in the process of preparing the neodymium iron boron material and/or additionally added Al. When the content of Al is 0-0.04 mas%, Al is generally an impurity Al introduced in the process of preparing the neodymium iron boron material.

In the present invention, the content of X is preferably 0.25 to 0.465mas%, for example, 0.42, 0.43 or 0.46 mas%.

In the present invention, the kind of X is preferably one or more of Ti, Nb, Zr and Hf, more preferably Ti and Nb, or Nb and Zr, or Ti, Nb and Zr.

When X includes Zr, the Zr content is preferably in the range of 0.01 to 0.3, for example 0.1, 0.25 or 0.28, mas%.

When the X includes Ti, the Ti content is preferably in the range of 0.1 to 0.3mas%, such as 0.14 or 0.2 mas%.

When the X comprises Nb, the Nb content is preferably in the range of 0.04 to 0.31mas%, such as 0.12, 0.15, 0.2 or 0.3 mas%.

When X comprises Ti and Nb, the mass ratio of Ti to Nb can be conventional in the art and is generally (0.01-100): 1, preferably (0.1 to 10): 1, e.g. 1: 2,2:1,2: 3 or 5: 2.

when X comprises Nb and Zr, the mass ratio of Nb to Zr can be conventional in the art, typically 1: (0.01 to 100), preferably 1: (0.1 to 10), for example, 1: 0.25, or 1:0.5, or 1: 1.4.

When X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr can be conventional in the field, and is generally (0.01-100): 1: (0.01-100), preferably (0.1-10): 1: (0.1 to 10), for example, 1: 2: 1.

in the invention, the X can also comprise Mn, and the content range of the Mn is 0-0.03 mas%, such as 0.01, 0.015 or 0.02 mas%.

In the present invention, the content of Co is preferably 0 to 0.2mas%, for example, 0.1 mas%.

In the present invention, the content of B is preferably 0.955 to 0.98mas%, for example, 0.96 or 0.964 mas%.

In the present invention, the content of Dy and/or Tb in the second component is preferably 0.5 to 0.8 mas%.

When the second component includes Dy, the content of Dy is preferably in the range of 0.2 to 1mas%, for example, 0.5 or 0.8 mas%. The addition form of Dy in the second component can be one or more of pure Dy, Dy alloy and Dy fluoride. Wherein the Dy alloy is preferably DyGaCu; in the DyGaCu alloy, the Dy content is preferably more than or equal to 75mas, more preferably more than or equal to 95mas, and the Dy content is the percentage of the total mass of the DyGaCu alloy.

When the second component comprises Tb, the content of Tb is preferably in the range of 0.2-1 mas%, for example 0.5 mas%. The Tb in the second component can be added in one or more of pure Tb, Tb alloy and Tb fluoride. The Tb alloy is preferably a TbGaCu alloy; in the TbGaCu alloy, the Tb content is preferably more than or equal to 75mas percent, more preferably more than or equal to 95mas percent, and the percentage is the percentage of the Tb consumption in the total mass of the TbGaCu alloy.

When the second component comprises a mixture of Dy and Tb, the mass ratio of Dy and Tb may be any value, typically 1: (0.01 to 100), preferably 1: (0.3 to 3), for example, 1:1.

in the invention, the total rare earth content in the raw material composition of the neodymium iron boron magnet material is generally 29.5-32.5 mas%, such as 30 mas%, 30.3 mas%, 30.6 mas%, 30.8 mas%, 30.9 mas%, 31.2 mas% or 32 mas%.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: nd, 27 mas%; ho, 4.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the second component: tb, 0.5 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the second component: dy, 0.5 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: PrNd, 28.5 mas%; ho, 1 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the second component: dy, 0.8 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the second component: dy, 0.2 mas%; tb, 0.2 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: nd, 25.8 mas%; ho, 4 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the second component: tb, 1 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: nd, 26 mas%; ho, 6 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the second component: dy, 0.5 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: PrNd, 21.6 mas%; ho, 8 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the second component: dy, 1 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the ndfeb magnet material includes: the first component: nd, 21 mas%; ho, 10 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the second component: dy, 0.2 mas%; the balance being Fe.

In the present invention, the raw material composition of the neodymium iron boron magnet material may contain inevitable impurities.

In the present invention, the "balance of Fe" does not exclude that other elements than the respective elements mentioned in the present invention are included in the raw material composition of the neodymium iron boron magnet material. When the raw material composition of the neodymium iron boron magnet material further comprises other elements except the elements mentioned in the invention, the amount of the Fe is correspondingly adjusted, so that the mass percentage of the elements except the Fe in the raw material composition of the neodymium iron boron magnet material is within the range defined by the invention.

The invention also provides a preparation method of the neodymium iron boron magnet material, which is carried out by adopting the raw material composition of the neodymium iron boron magnet material, and the preparation method comprises the following steps:

s1, smelting, pulverizing, molding and sintering the first component to obtain a neodymium iron boron sintered body;

s2, performing grain boundary diffusion on the neodymium iron boron sintered body obtained in the step S1 by adopting the second component;

and S3, carrying out heat treatment to obtain the neodymium iron boron magnet material.

In the present invention, in step S1, the smelting operation and conditions may be a smelting process that is conventional in the art, and generally, each element of the first component is smelted and cast by an ingot casting process or a rapid hardening sheet process to obtain an alloy sheet.

In the present invention, in step S1, the temperature of the melting may be 1300 to 1700 ℃, for example, 1500 ℃.

In the present invention, in step S1, the melting equipment is generally a high frequency vacuum melting furnace and/or a medium frequency vacuum melting furnace. The medium-frequency vacuum smelting furnace can be a medium-frequency vacuum induction rapid hardening melt-spun furnace.

As known to those skilled in the art, since rare earth elements are usually lost in the melting and sintering processes, in order to ensure the quality of a final product, 0 to 0.3mas% of a rare earth element (generally Nd element) is generally additionally added to the formulation of a raw material composition in the melting process, and the percentage is the mass percentage of the additionally added rare earth element in the total content of the raw material composition; in addition, the content of the additionally added rare earth elements is not included in the category of the raw material composition.

In the present invention, in step S1, the milling operation and conditions may be conventional milling processes in the art, and generally include hydrogen milling and/or gas stream milling.

The hydrogen pulverized powder generally comprises hydrogen absorption, dehydrogenation and cooling treatment. The temperature of the hydrogen absorption is generally 20 to 200 ℃, preferably 20 to 40 ℃ (i.e. room temperature). The pressure of the hydrogen absorption is generally 50 to 600kPa, for example 90 kPa. The dehydrogenation temperature is generally 400 to 650 ℃, for example 550 ℃.

The gas flow in the gas flow milled powder can be, for example, nitrogen and/or argon. The pressure of the airflow milled powder is generally 0.1-2 MPa, preferably 0.5-0.7 MPa, such as 0.65 MPa. The efficiency of the jet milled powder may vary depending on the equipment, and may be, for example, 30 to 400kg/h, preferably 200 kg/h.

In the present invention, in step S1, the molding operation and conditions may be a molding process conventional in the art, such as a magnetic field molding process. The magnetic field intensity of the magnetic field forming method is generally 1.5T or more.

In the present invention, in step S1, the sintering operation and conditions may be sintering processes conventional in the art, such as a vacuum sintering process and/or an inert atmosphere sintering process. The vacuum sintering process or the inert atmosphere sintering process are all conventional operations in the field. When an inert atmosphere sintering process is used, the sintering initiation stage may be performed under a vacuum of less than 0.5 Pa. The inert atmosphere may be an atmosphere containing an inert gas as is conventional in the art, such as helium or argon.

In the present invention, in step S1, the sintering temperature may be 1000 to 1200 ℃, preferably 1030 to 1090 ℃.

In the present invention, in step S1, the sintering time may be 0.5 to 10 hours, preferably 2 to 8 hours.

In the present invention, in step S2, the operation and condition of grain boundary diffusion may be a grain boundary diffusion process that is conventional in the art, and generally the second component is applied to the sintered nd-fe-b body and then subjected to heat preservation. Wherein, the application mode can be coating, magnetron plasma sputtering or evaporation.

The operation and conditions of the coating may be conventional in the art, and the second component is typically coated on the neodymium iron boron sintered body in the form of fluoride or low melting point alloy. When the second component comprises Tb, preferably Tb is applied in the form of a fluoride of Tb or a low melting point alloy. When the second component contains Dy, preferably Dy is coated in the form of a fluoride or a low melting point alloy of Dy.

The operation and conditions of the magnetron plasma sputtering can be conventional in the art, and generally, the target material of the second component is bombarded by inert gas to generate Dy and/or Tb ions, and the Dy and/or Tb ions are uniformly attached to the surface of the neodymium iron boron sintered body under the control of a magnetic field.

The operation and conditions of the evaporation may be conventional in the art and are generally achieved by shaping the metal of the second component and evacuating it to a set value (e.g. 5Pa to 5 x 10) in a vacuum diffusion furnace^-2Pa) and heating to a set temperature (such as 500-900 ℃) to generate Dy and/or Tb vapor, so that the Dy and/or Tb vapor is enriched on the surface of the neodymium iron boron sintered body.

In the present invention, in step S2, the temperature of the grain boundary diffusion may be 800 to 1000 ℃, preferably 850 to 950 ℃, and more preferably 900 ℃. The time of the grain boundary diffusion can be 12-90 h, such as 24 h.

In the present invention, in step S3, the temperature of the heat treatment may be 480 to 510 ℃. The heat treatment time can be 2-4 hours.

The invention also provides a neodymium iron boron magnet material which is prepared by the preparation method of the neodymium iron boron magnet material.

The invention also provides a neodymium iron boron magnet material, which comprises:

a light rare earth element (LR), the LR including Nd;

ho, 0-10 mas%, and not 0;

dy and/or Tb 0.2-1 mas%;

Cu，0.35～0.6mas％；

C，0～0.32mas％；

ga, 0-0.42 mas%, and is not 0;

Co，0～0.5mas％；

Al，0～0.5mas％；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9～1.05mas％；

the balance being Fe;

mas% is the mass percentage of each element in the neodymium iron boron magnet material;

the microstructure of the neodymium iron boron magnet material comprises a main phase, a grain boundary epitaxial layer and a neodymium-rich phase; ho is distributed on the main phase and the crystal boundary epitaxial layer, Dy or Tb is not distributed on the main phase, Cu and Dy and/or Tb are distributed on the neodymium-rich phase, and the crystal boundary continuity of the neodymium-iron-boron magnet material is more than 96.5%.

In the present invention, the main structure of the main phase is Nd which is conventional in the art₂Fe_l4B crystal grains. The intergranular epilayer generally refers to a two-particle grain boundary adjacent to the neodymium-rich phase and the main phase, and may also be referred to as a "two-particle grain boundary" or as a "grain boundary edge shell structure of the main phase and the neodymium-rich phase". The neodymium-rich phase is a neodymium-rich phase conventionally understood in the art, and the phase structure in the grain boundary structure in the art is mostly a neodymium-rich phase.

In the invention, more than 95% of the total mass of Ho element is preferably distributed in the main phase and the crystal boundary epitaxial layer. That is, only a small portion of the Ho element is distributed in the neodymium-rich phase.

In the invention, more than 70% of the total mass of Cu element is preferably distributed in the neodymium-rich phase.

In the present invention, the calculation method of the grain boundary continuity refers to a ratio of a length occupied by phases (for example, neodymium-rich phase and phase equal to each other in the grain boundary epitaxial layer) other than the voids in the grain boundary to the total grain boundary length. The grain boundary continuity is preferably 96.7% to 97.8%, such as 96.8%, 97.2%, 97.3%, 97.4% or 97.7%.

In the present invention, the content of Nd is preferably 16 to 27mas%, for example, 16.2, 21, 21.4, 24, 25.8, 26 or 26.5 mas%.

In the present invention, the LR may also include other light rare earth elements conventional in the art, including, for example, Pr and/or Sm. When the LR contains Pr, the content of the Pr can be 0-16 mas percent and is not 0; preferably 3-7, such as 5, mas%. When the LR contains Sm, the content of the Sm can be 0-5 mas percent and is not 0; for example 2.5 mas%.

In the present invention, the content of Ho is preferably 0.5 to 8mas%, for example, 1, 2, 4, 4.5 or 6 mas%.

In the present invention, the content of Dy and/or Tb is preferably 0.5 to 0.8 mas%.

When the ndfeb magnet material includes Dy, the content of Dy is preferably in the range of 0.2 to 1mas%, for example, 0.5 or 0.8 mas%.

When the ndfeb magnet material includes Tb, the content range of Tb is preferably 0.2-1 mas%, for example 0.5 mas%.

When the neodymium iron boron magnet material includes a mixture of Dy and Tb, the mass ratio of Dy and Tb may be any value, and is generally 1: (0.01 to 100), preferably 1: (0.3 to 3), for example, 1:1.

in the present invention, the content range of Cu is preferably 0.4 to 0.55mas%, for example, 0.45, 0.5 or 0.52 mas%.

In the present invention, the content range of C is preferably 0.07 to 0.2mas%, for example, 0.098, 0.12, 0.15 or 0.16 mas%. When the content of C is 0 to 0.12mas%, C may be an impurity C introduced in the process of preparing the neodymium iron boron material, for example, a lubricant and the like are generally added in the preparation process to introduce the C impurity.

In the present invention, the content range of Ga is preferably 0.06 to 0.3mas%, for example, 0.07, 0.09, 0.15 mas%.

In the present invention, the content of Al is preferably 0 to 0.3mas%, more preferably 0 to 0.1mas%, such as 0.01, 0.02, 0.04, or 0.05 mas%. When the content of Al is 0-0.1 mas%, the Al can be impurity Al introduced in the process of preparing the neodymium iron boron material and/or additionally added Al. When the content of Al is 0-0.04 mas%, Al is generally an impurity Al introduced in the process of preparing the neodymium iron boron material.

In the present invention, the content of X is preferably 0.25 to 0.465mas%, for example, 0.42, 0.43 or 0.46 mas%.

In the present invention, the kind of X is preferably one or more of Ti, Nb, Zr and Hf, more preferably Ti and Nb, or Nb and Zr, or Ti, Nb and Zr.

When X includes Zr, the Zr content is preferably in the range of 0.01 to 0.3, for example 0.1, 0.25 or 0.28, mas%.

When the X includes Ti, the Ti content is preferably in the range of 0.1 to 0.3mas%, such as 0.14 or 0.2 mas%.

When X comprises Nb, the Nb content is preferably in the range of 0.04 to 0.31mas%, e.g., 0.12, 0.15, 0.2 or 0.3mas%

When X comprises Ti and Nb, the mass ratio of Ti to Nb can be conventional in the art and is generally (0.01-100): 1, preferably (0.1 to 10): 1, e.g. 1: 2,2:1,2: 3 or 5: 2.

when X comprises Nb and Zr, the mass ratio of Nb to Zr can be conventional in the art, typically 1: (0.01 to 100), preferably 1: (0.1 to 10), for example, 1: 0.25, or 1:0.5, or 1: 1.4.

When X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr can be conventional in the field, and is generally (0.01-100): 1: (0.01-100), preferably (0.1-10): 1: (0.1 to 10), for example, 1: 2: 1.

in the invention, the X can also comprise Mn, and the content range of the Mn is 0-0.03 mas%, such as 0.01, 0.015 or 0.02 mas%.

In the present invention, the content of Co is preferably 0 to 0.2mas%, for example, 0.1 mas%.

In the present invention, the content of B is preferably 0.955 to 0.98mas%, for example, 0.96 or 0.964 mas%.

In the invention, the total rare earth content in the raw material composition of the neodymium iron boron magnet material is generally 29.5-32.5 mas%, such as 30 mas%, 30.3 mas%, 30.6 mas%, 30.8 mas%, 30.9 mas%, 31.2 mas% or 32 mas%.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 27 mas%; ho, 4.5 mas%; tb, 0.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; dy, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 21.4 mas%; pr, 7.1 mas%; ho, 1 mas%; dy, 0.8 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; dy, 0.2 mas%; tb, 0.2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 25.8 mas%; ho, 4 mas%; tb, 1 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 26 mas%; ho, 6 mas%; dy, 0.5 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 16.2 mas%; pr, 5.4 mas%; ho, 8 mas%; dy, 1 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the ndfeb magnet material includes: nd, 21 mas%; ho, 10 mas%; dy, 0.2 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the balance being Fe.

In the present invention, the neodymium iron boron magnet material may contain inevitable impurities.

In the present invention, the "balance of Fe" does not exclude that other elements than the elements mentioned in the present invention are included in the neodymium iron boron magnet material. When the neodymium iron boron magnet material further comprises other elements except the elements mentioned in the invention, the amount of the Fe is correspondingly adjusted, so that the mass percentage of the elements except the Fe in the neodymium iron boron magnet material is within the range defined by the invention.

The invention also provides a raw material composition of the neodymium iron boron sintered body, which comprises the following components:

a light rare earth element (LR), the LR including Nd;

ho, 0-10 mas%, and not 0;

Cu，0.35～0.6mas％；

C，0～0.32mas％；

ga, 0-0.42 mas%, and is not 0;

Co，0～0.5mas％；

Al，0～0.5mas％；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9～1.05mas％；

the raw material composition of the neodymium iron boron sintered body does not contain other heavy rare earth elements except Ho;

the balance being Fe;

and mas percent is the mass percentage of each element in the raw material composition of the neodymium iron boron sintered body.

In the present invention, the content of Nd is preferably 16 to 27mas%, for example, 16.2, 21, 21.4, 24, 25.8, 26 or 26.5 mas%.

In the present invention, the LR may also include other light rare earth elements conventional in the art, including, for example, Pr and/or Sm. When the LR contains Pr, the content of the Pr can be 0-16 mas percent and is not 0; preferably 3-7, such as 5, mas%. The Pr can be added in the form of pure Pr and/or PrNd, preferably PrNd. The PrNd is an alloy of Pr and Nd, and the mass ratio of Pr to Nd in the PrNd is generally 25:75 or 20: 80. when the LR contains Sm, the content of the Sm can be 0-5 mas percent and is not 0; for example 2.5 mas%.

In the present invention, the content of Ho is preferably 0.5 to 8mas%, for example, 1, 2, 4, 4.5 or 6 mas%.

In the present invention, the content range of Cu is preferably 0.4 to 0.55mas%, for example, 0.45, 0.5 or 0.52 mas%.

In the present invention, the content range of C is preferably 0.07 to 0.2mas%, for example, 0.098, 0.12, 0.15 or 0.16 mas%. When the content of C is 0 to 0.12mas%, C may be an impurity C introduced in the process of preparing the neodymium iron boron material, for example, a lubricant and the like are generally added in the preparation process to introduce the C impurity.

In the present invention, the content range of Ga is preferably 0.06 to 0.3mas%, for example, 0.07, 0.09, 0.15 mas%.

In the present invention, the content of Al is preferably 0 to 0.3mas%, more preferably 0 to 0.1mas%, such as 0.01, 0.02, 0.04, or 0.05 mas%. When the content of Al is 0-0.1 mas%, the Al can be impurity Al introduced in the process of preparing the neodymium iron boron sintered body and/or additionally added Al. When the content of Al is 0-0.04 mas%, Al is generally an impurity Al introduced in the process of preparing the neodymium iron boron sintered body.

In the present invention, the content of X is preferably 0.25 to 0.465mas%, for example, 0.42, 0.43 or 0.46 mas%.

In the present invention, the kind of X is preferably one or more of Ti, Nb, Zr and Hf, more preferably Ti and Nb, or Nb and Zr, or Ti, Nb and Zr.

When X includes Zr, the Zr content is preferably in the range of 0.01 to 0.3, for example 0.1, 0.25 or 0.28, mas%.

When the X includes Ti, the Ti content is preferably in the range of 0.1 to 0.3mas%, such as 0.14 or 0.2 mas%.

When the X comprises Nb, the Nb content is preferably in the range of 0.04 to 0.31mas%, such as 0.12, 0.15, 0.2 or 0.3 mas%.

When X comprises Ti and Nb, the mass ratio of Ti to Nb can be conventional in the art and is generally (0.01-100): 1, preferably (0.1 to 10): 1, e.g. 1: 2,2:1,2: 3 or 5: 2.

when X comprises Nb and Zr, the mass ratio of Nb to Zr can be conventional in the art, typically 1: (0.01 to 100), preferably 1: (0.1 to 10), for example, 1: 0.25, or 1:0.5, or 1: 1.4.

When X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr can be conventional in the field, and is generally (0.01-100): 1: (0.01-100), preferably (0.1-10): 1: (0.1 to 10), for example, 1: 2: 1.

in the invention, the X can also comprise Mn, and the content range of the Mn is 0-0.03 mas%, such as 0.01, 0.015 or 0.02 mas%.

In the present invention, the content of Co is preferably 0 to 0.2mas%, for example, 0.1 mas%.

In the present invention, the content of B is preferably 0.955 to 0.98mas%, for example, 0.96 or 0.964 mas%.

In the invention, the total rare earth content in the raw material composition of the neodymium iron boron magnet material is generally 28.5-32.3 mas%, such as 29.5, 29.6, 29.8, 30.5, 31, 31.5 or 32 mas%.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: nd, 27 mas%; ho, 4.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: PrNd, 28.5 mas%; ho, 1 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: nd, 25.8 mas%; ho, 4 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: nd, 26 mas%; ho, 6 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: PrNd, 21.6 mas%; ho, 8 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the raw material composition of the neodymium iron boron sintered body includes: nd, 21 mas%; ho, 10 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the balance being Fe.

In the present invention, the raw material composition of the neodymium iron boron sintered body may contain inevitable impurities.

In the present invention, the "balance of Fe" does not exclude that other elements than the respective elements mentioned in the present invention are included in the raw material composition of the neodymium iron boron sintered body. When the raw material composition of the neodymium iron boron sintered body further comprises other elements except the elements mentioned in the invention, the amount of the Fe is correspondingly adjusted, so that the mass percentage of the elements except the Fe in the raw material composition of the neodymium iron boron magnet material is within the range defined by the invention.

The invention also provides a preparation method of the neodymium iron boron sintered body, which comprises the steps of smelting, milling, forming and sintering the raw material composition of the neodymium iron boron sintered body. Wherein the processes of the smelting, the milling, the forming and the sintering are the same as above.

The invention also provides a neodymium iron boron sintered body, which is prepared by the preparation method of the neodymium iron boron sintered body.

The present invention also provides a neodymium iron boron sintered body, which includes:

a light rare earth element (LR), the LR including Nd;

ho, 0-10 mas%, and not 0;

Cu，0.35～0.6mas％；

C，0～0.32mas％；

ga, 0-0.42 mas%, and is not 0;

Co，0～0.5mas％；

Al，0～0.5mas％；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9～1.05mas％；

the neodymium iron boron sintered body does not contain other heavy rare earth elements except Ho;

the balance being Fe;

mas% is the mass percentage of each element in the neodymium iron boron sintered body;

the microstructure of the neodymium iron boron sintered body comprises a main phase, a grain boundary epitaxial layer and a neodymium-rich phase; ho is distributed on the main phase and the crystal boundary epitaxial layer, Cu is distributed on the neodymium-rich phase, and the continuity of the crystal boundary of the neodymium-iron-boron sintered body is more than 96%.

Wherein the main phase, the grain boundary epitaxial layer, the neodymium-rich phase and the grain boundary continuity are defined and explained as above.

In the present invention, the content of Nd is preferably 16 to 27mas%, for example, 16.2, 21, 21.4, 24, 25.8, 26 or 26.5 mas%.

In the present invention, the LR may also include other light rare earth elements conventional in the art, including, for example, Pr and/or Sm. When the LR contains Pr, the content of the Pr can be 0-16 mas percent and is not 0; preferably 3-7, such as 5, mas%. When the LR contains Sm, the content of the Sm can be 0-5 mas percent and is not 0; for example 2.5 mas%.

In the present invention, the content of Ho is preferably 0.5 to 8mas%, for example, 1, 2, 4, 4.5 or 6 mas%.

In the present invention, the content range of Cu is preferably 0.4 to 0.55mas%, for example, 0.45, 0.5 or 0.52 mas%.

In the present invention, the content range of C is preferably 0.07 to 0.2mas%, for example, 0.098, 0.12, 0.15 or 0.16 mas%. When the content of C is 0 to 0.12mas%, C may be an impurity C introduced in the process of preparing the neodymium iron boron material, for example, a lubricant and the like are generally added in the preparation process to introduce the C impurity.

In the present invention, the content range of Ga is preferably 0.06 to 0.3mas%, for example, 0.07, 0.09, 0.15 mas%.

In the present invention, the content of Al is preferably 0 to 0.3mas%, more preferably 0 to 0.1mas%, such as 0.01, 0.02, 0.04, or 0.05 mas%. When the content of Al is 0-0.1 mas%, the Al can be impurity Al introduced in the process of preparing the neodymium iron boron sintered body and/or additionally added Al. When the content of Al is 0-0.04 mas%, Al is generally an impurity Al introduced in the process of preparing the neodymium iron boron sintered body.

In the present invention, the content of X is preferably 0.25 to 0.465mas%, for example, 0.42, 0.43 or 0.46 mas%.

In the present invention, the kind of X is preferably one or more of Ti, Nb, Zr and Hf, more preferably Ti and Nb, or Nb and Zr, or Ti, Nb and Zr.

When X includes Zr, the Zr content is preferably in the range of 0.01 to 0.3, for example 0.1, 0.25 or 0.28, mas%.

When the X includes Ti, the Ti content is preferably in the range of 0.1 to 0.3mas%, such as 0.14 or 0.2 mas%.

When X comprises Nb, the Nb content is preferably in the range of 0.04 to 0.31mas%, e.g., 0.12, 0.15, 0.2 or 0.3mas%

When X comprises Ti and Nb, the mass ratio of Ti to Nb can be conventional in the art and is generally (0.01-100): 1, preferably (0.1 to 10): 1, e.g. 1: 2,2:1,2: 3 or 5: 2.

when X comprises Nb and Zr, the mass ratio of Nb to Zr can be conventional in the art, typically 1: (0.01 to 100), preferably 1: (0.1 to 10), for example, 1: 0.25, or 1:0.5, or 1: 1.4.

When X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr can be conventional in the field, and is generally (0.01-100): 1: (0.01-100), preferably (0.1-10): 1: (0.1 to 10), for example, 1: 2: 1.

in the invention, X can also comprise Mn, and the content of Mn is in the range of 0-0.03 mas%, such as 0.01, 0.015 or 0.02 mas%.

In the present invention, the content of Co is preferably 0 to 0.2mas%, for example, 0.1 mas%.

In the present invention, the content of B is preferably 0.955 to 0.98mas%, for example, 0.96 or 0.964 mas%.

In the invention, the total rare earth content in the neodymium iron boron magnet material is generally 28.5-32.3 mas%, such as 29.5, 29.6, 29.8, 30.5, 31, 31.5 or 32 mas%.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 27 mas%; ho, 4.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 21.4 mas%; pr, 7.1 mas%; ho, 1 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 25.8 mas%; ho, 4 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 26 mas%; ho, 6 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 16.2 mas%; pr, 5.4 mas%; ho, 8 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the balance being Fe.

In a preferred embodiment of the present invention, the neodymium iron boron sintered body includes: nd, 21 mas%; ho, 10 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the balance being Fe.

In the present invention, the neodymium iron boron sintered body may contain inevitable impurities.

In the present invention, the "balance of Fe" does not exclude that other elements than the respective elements mentioned in the present invention are included in the neodymium iron boron sintered body. When the neodymium iron boron sintered body further comprises other elements except the elements mentioned in the invention, the amount of the Fe is correspondingly adjusted, so that the mass percentage of the elements except the Fe in the neodymium iron boron magnet material is within the range defined by the invention.

The invention also provides the application of the neodymium iron boron magnet material or the neodymium iron boron sintered body in the preparation of magnetic steel.

On the basis of the common knowledge in the field, the above preferred conditions can be combined randomly to obtain the preferred embodiments of the invention.

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

The positive progress effects of the invention are as follows:

1. according to the invention, by adding a proper amount of Cu during smelting and a proper amount of heavy rare earth element Ho, when no or low Co and no or low Al exist, the remanence and coercive force of the material are adjusted within a specific range, and the high-temperature stability is improved, specifically:

1) at normal temperature, the residual magnetism Br of the neodymium iron boron magnet material can be 11.8-14.2 kGs, and the magnetic polarization strength coercive force Hcj is 26.7-30.8 kOe; at a high temperature (140 ℃), Br is 10.45-12.55 kGs, and Hcj is 12.8-16.3 kOe.

2) At normal temperature, Br of the neodymium iron boron sintered body is 11.85-14.24 kGs, and Hcj is 16.5-21.8 kOe; the increase of Hcj after diffusion is 8 to 11.7 kOe.

3) Based on the formula components of the application, the high-temperature resistant performance is good due to the matching of all elements: the absolute value of the Br temperature coefficient alpha of the neodymium iron boron magnet material is 0.088-0.096%, the absolute value of the Hcj temperature coefficient beta is 0.39-0.436%, and the full open-circuit magnetic loss is 0.05-0.78%.

2. The neodymium iron boron magnet material also has good corrosion resistance.

Drawings

FIG. 1 is an SEM photograph of a sintered Nd-Fe-B body in example 1 of the present invention;

wherein, 1, a main phase, 2, a grain boundary epitaxial layer, 3 and a neodymium-rich phase.

Fig. 2 is an EPMA spectrum of the neodymium iron boron magnet material prepared in example 1 of the present invention.

Detailed Description

The invention is further illustrated by the following examples, which are not intended to limit the scope of the invention. The experimental methods without specifying specific conditions in the following examples were selected according to the conventional methods and conditions, or according to the commercial instructions.

Preparation examples

The neodymium iron boron magnet materials in examples 1 to 19 and comparative examples 1 to 8 were prepared according to the following preparation processes:

s1, smelting, pulverizing, molding and sintering the first component, wherein the first component is specifically as follows:

(1) smelting and casting: elements of the first composition in table 1 (i.e., elements in table 2) were put into a crucible of alumina, and vacuum melting was performed in a high-frequency vacuum melting furnace under a vacuum of 0.05Pa at 1500 ℃; transferring the alloy sheet to a medium-frequency vacuum induction rapid hardening melt-spun furnace, introducing argon, casting and quenching to obtain an alloy sheet.

(2) Hydrogen crushing to obtain powder: placing the alloy sheet in a hydrogen breaking furnace, vacuumizing the hydrogen breaking furnace at room temperature, introducing hydrogen with the purity of 99.9% into the hydrogen breaking furnace, and maintaining the pressure of the hydrogen at 90kPa to ensure that the alloy sheet fully absorbs hydrogen; then, vacuumizing and heating to 550 ℃ at the same time to fully dehydrogenate the alloy sheet; and then cooling to obtain powder.

(3) Milling powder by airflow: the powder obtained from the hydrogen-pulverized powder was pulverized by jet milling under a nitrogen atmosphere at a pressure of 0.65MPa (the efficiency of the jet milling powder may vary depending on the equipment, and may be, for example, 200kg/h) to obtain a fine powder.

(4) Magnetic field forming: and pressing and molding the fine powder obtained by milling the powder by airflow in the magnetic field intensity of more than 1.5T to obtain a molded body.

(5) Sintering in inert atmosphere: and transferring the formed body to a sintering furnace, and sintering for 2-8 h at the temperature of 1030-1090 ℃ under the atmosphere of helium and under the condition that the vacuum degree is lower than 0.5Pa to obtain the neodymium iron boron sintered body.

S2, performing grain boundary diffusion on the neodymium iron boron sintered body by adopting a second component in the table 1, which is specifically as follows:

and (5) purifying the surface of the neodymium iron boron sintered body obtained in the step (S1), coating the second component on the surface of the neodymium iron boron sintered body, diffusing at 900 ℃ for 24h, and then cooling to room temperature.

S3, heat treatment: and (3) carrying out heat treatment at 480-510 ℃ for 3h to obtain the neodymium iron boron magnet material.

TABLE 1 formulation and content (mas%) of raw material composition of NdFeB magnet Material

The mass ratio of Pr to Nd in the PrNd alloy is 25: 75.

TABLE 2 formulation and content (mas%) of raw material composition of NdFeB sintered body

The mass ratio of Pr to Nd in the PrNd alloy is 25: 75.

Effect example 1: determination of material composition

The components of the neodymium iron boron magnet material (after diffusion) and the neodymium iron boron sintered body (before diffusion) in the examples and comparative examples were measured using a high frequency inductively coupled plasma emission spectrometer (ICP-OES) using a method conventional in the art, and the measurement results are shown in tables 3 and 4, respectively.

TABLE 3 composition and content (mas%) of NdFeB magnet Material

TABLE 4 composition and content (mas%) of Nd-Fe-B sintered body

Effect example 2: microstructure determination

1. SEM analysis

SEM images of the sintered nd-Fe-B bodies and the nd-Fe-B magnet materials in examples 1 to 8 and comparative examples 1 to 4 were measured using an SEM-EDS backscatter apparatus (model: Hitachi S-3400N). The SEM image of the sintered nd-fe-b body obtained in example 1 is shown in fig. 1.

Fig. 1 is an SEM image of the sintered nd-fe-b body obtained in example 1, which contains Cu (0.52 mas%) and does not contain Al and Co, and which contains Ho as a heavy rare earth element. As can be seen from fig. 1, the neodymium-iron-boron sintered body includes a main phase 1 (dark gray region), a grain boundary epitaxial layer 2 (light gray region), and a neodymium-rich phase 3 (white region), which is relatively uniformly distributed among main phase grains and is relatively large. The neodymium-rich phase uniformly distributed along the grain boundary can reduce the ferromagnetism of the main phase boundary phase, is more favorable for the magnetic isolation effect of the main phase and effectively preventing the expansion of a reverse magnetic domain on the main phase, promotes the diffusion of the subsequent diffusion element Dy or/and Tb, and improves the coercive force of the product.

2. SEM-EDS analysis

On the basis of fig. 1, the elemental composition of the neodymium iron boron sintered body obtained in example 1 in the sampling range was calculated by EDS test in SEM electron microscope, and the result is shown in table 5.

TABLE 5

Sampling points in FIG. 1	Physical phase	Nd/mas％	Ho/mas％	Cu/mas％	C/mas％
						1	Main phase	26.51	4.54	0.28	0.075
2	Grain boundary epitaxial layer	48.75	4.35	0.62	0.067
						3	Phase rich in neodymium	78.55	4.05	1.02	0.082

Note: taking sample point 1 as an example, the sample point belongs to a main phase, and within the sampling range, the Nd content is 26.51 mas%, the Ho content is 4.54 mas%, the Cu content is 0.28mas%, and the C content is 0.075 mas%, wherein the percentages are mass percentages of the total mass of all elements in the sampling range.

As can be seen from Table 5, the Ho element mainly enters the main phase, and Ho has a certain effect of improving the anisotropy field of the main phase, and thus Hcj can be increased. Meanwhile, because the Ho element enters and partially replaces Nd in the main phase, more Nd is transferred to the Nd-rich phase, the ratio of the Nd-rich phase is increased, and more diffusion channels are provided for subsequent Dy or/and Tb diffusion. The Ho element also has a certain distribution in the grain boundary epitaxial layer. In the crystal boundary epitaxial layer, the concentration of the heavy rare earth element is increased, the concentration difference between the diffused heavy rare earth element and the main phase is reduced in the diffusion process, the diffusion of the diffused element to the main phase is avoided, the diffusion along the crystal boundary epitaxial layer is preferentially performed, the diffusion of the diffused heavy rare earth element along the neodymium-rich phase is further increased, and the diffusion depth and the diffusion speed are increased.

The Cu element is mainly distributed in the neodymium-rich phase, and the addition of the Cu can reduce the melting point of the neodymium-rich phase, so that the neodymium-rich phase and the main phase have a good wetting effect, and the distribution of the neodymium-rich phase is improved. In addition, Cu also forms NdCu which is not easy to corrode with Nd₂A compound, increasing the corrosion resistance of the material. However, when the Cu content is too large (more than 0.6 mas%), the amount of Nd consumed for forming a Nd-rich phase is reduced, the number of grain boundaries formed is reduced, and the coercivity of the product is drastically reduced.

3. EPMA analysis

The EPMA spectrum of the NdFeB magnet material prepared in example 1 was measured using a micro-area X-ray spectrometer (model: EPMA-1720) and is shown in FIG. 2. Fig. 2 shows the distribution of Tb in the ndfeb magnet material, and it can be seen from fig. 2 that after Tb diffusion, Tb element does not enter the main phase but is mainly concentrated in the nd-rich phase in the ndfeb sintered body of example 1. The crystal grain boundary neodymium-rich phase is obviously clear after Tb is diffused, the occupation ratio of the neodymium-rich phase to the crystal grain boundary epitaxial layer is increased, more replaced Nd is distributed along the periphery of the main phase, the continuity of the crystal grain boundary is increased, direct exchange coupling between the main phases is prevented, and the coercive force is obviously improved.

4. Continuity of grain boundaries

Grain boundary continuity refers to the ratio of the length occupied by phases other than voids (e.g., neodymium-rich phase, grain boundary epitaxial layer) in the grain boundary to the total grain boundary length. If the continuity of the grain boundary exceeds 96%, the channel is called a continuous channel. Grain boundary continuity was calculated based on SEM images of the neodymium iron boron magnet materials of each example and comparative example. The grain boundary continuity of the neodymium-iron-boron magnet materials in examples 1 to 8 and comparative examples 1 to 4 is shown in table 6. The grain boundary continuity of the neodymium-iron-boron magnet materials of examples 1 to 8 was 96.5% or more, and the grain boundary continuity of the neodymium-iron-boron magnet materials of comparative examples 1 to 4 was 96.5% or less.

TABLE 6 grain boundary continuity of NdFeB magnet materials

Effect example 3: magnetic property test

Magnetic properties of each of the samples of examples and comparative examples were measured using a PFM-14 magnetic property measuring instrument (test sample is a disc having a diameter D10mm × thickness of 1.8 mm) of Hirst, UK. and the results are shown in Table 7.

TABLE 7 magnetic Property test results

The data in table 7 are illustrated below:

1. br (kgs): remanence, namely magnetism which can be kept by an external magnetic field is removed after the permanent magnetic material is magnetized in a saturated way.

2. Hcj (koe): the coercive force of the magnetic polarization strength is also called intrinsic coercive force.

3.Δ hcj (koe): the coercive force Hcj of the magnetic polarization strength of the neodymium iron boron magnet material after diffusion is increased relative to the coercive force of the magnetic polarization strength of the neodymium iron boron sintered body before diffusion at normal temperature (20 ℃).

Br temperature coefficient α absolute value (%): the temperature coefficient is calculated based on the remanence Br of the neodymium iron boron magnet material at normal temperature (20 ℃) and high temperature (140 ℃), and the calculation formula is as follows:

hcj temperature coefficient β absolute value (%): the temperature coefficient is calculated based on the magnetic polarization strength coercive force Hcj of the neodymium iron boron magnet material at normal temperature (20 ℃) and high temperature (140 ℃), and the calculation formula is as follows:

6. full open circuit magnetic loss (%): the neodymium iron boron magnet material is baked for a certain time (such as 120min) at high temperature (140 ℃), the full open circuit magnetic loss is calculated based on the magnetic flux change of the neodymium iron boron magnet material before and after baking, and the calculation formula is as follows:

wherein, the magnetic flux of the neodymium iron boron magnet material is measured at normal temperature (20 ℃) and is marked as M1; then heating the neodymium iron boron magnet material in an oven to a set temperature of 140 ℃, preserving the heat for 120min, cooling to the normal temperature, and measuring the magnetic flux, wherein the magnetic flux is recorded as M2.

Analysis of the results of the magnetic property tests in Table 7:

1) comparative example 1: based on example 7, the Cu content was increased to be excessive, and other conditions were not changed.

At room temperature, Br and Hcj of the neodymium iron boron sintered body and the neodymium iron boron magnet material in comparative example 1 are both slightly reduced, and the coercive force increase (Δ Hcj) after diffusion is small (about 0.55 times that of example 7) compared to example 7. At high temperature, compared to example 7, the neodymium-iron-boron magnet material in comparative example 1 has smaller Hcj, larger absolute values of Br temperature coefficient α and Hcj temperature coefficient β, larger full open-circuit magnetic loss (about 4.5 times that of example 7), and poorer high-temperature performance.

2) Comparative example 2: based on example 4, the C content was increased to make it excessive, and other conditions were not changed.

At room temperature, Br and Hcj of the neodymium iron boron sintered body and the neodymium iron boron magnet material in comparative example 2 are both slightly reduced, and the coercive force increase (Δ Hcj) after diffusion is small (about 0.8 times that of example 4) compared to example 4. At high temperature, compared to example 4, the neodymium-iron-boron magnet material in comparative example 2 has smaller Hcj, larger absolute values of Br temperature coefficient α and Hcj temperature coefficient β, larger full open-circuit magnetic loss (about 8.7 times that of example 4), and poorer high-temperature performance.

3) Comparative example 3: based on example 3, the Ga content was increased to make it excessive, and other conditions were not changed.

At normal temperature, Br and Hcj of the neodymium iron boron sintered body and the neodymium iron boron magnet material in comparative example 3 are both slightly reduced, and the coercivity increase after diffusion (Δ Hcj) is small (about 0.7 times that of example 3) compared to example 3. At high temperature, compared to example 3, the neodymium-iron-boron magnet material in comparative example 3 has smaller Hcj, larger absolute values of Br temperature coefficient α and Hcj temperature coefficient β, larger full open-circuit magnetic loss (about 13.8 times that of example 4), and poorer high-temperature performance.

4) Comparative example 4: based on example 6, no element X was contained and other conditions were unchanged.

At room temperature, Br and Hcj of the neodymium iron boron sintered body and the neodymium iron boron magnet material in comparative example 4 are both slightly reduced, and the coercive force increase (Δ Hcj) after diffusion is small (about 0.8 times that of example 3) compared to example 6. At high temperature, compared to example 6, the neodymium-iron-boron magnet material in comparative example 4 has smaller Hcj, larger absolute values of Br temperature coefficient α and Hcj temperature coefficient β, larger full open-circuit magnetic loss (about 63 times that of example 4), and poorer high-temperature performance.

Claims (28)

1. A neodymium iron boron magnet material, comprising:

a light rare earth element LR, wherein LR is Nd; or, the LR comprises Nd, and further comprises Pr and/or Sm; wherein the content of Nd is 16-27 mas%; when the LR contains Pr, the content of the Pr is 0-16 mas% and is not 0 mas%; when the LR contains Sm, the content of the Sm is 0-5 mas percent and is not 0;

Ho，0.5~10mas%；

dy and/or Tb 0.2-1 mas%;

Cu，0.4~0.6mas%；

C，0~0.32mas%；

ga, 0-0.42 mas%, and is not 0;

Co，0~0.5mas%；

Al，0~0.5mas%；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9~1.05mas%；

the balance being Fe;

mas% is the mass percentage of each element in the neodymium iron boron magnet material;

the microstructure of the neodymium iron boron magnet material comprises a main phase, a grain boundary epitaxial layer and a neodymium-rich phase; ho is distributed on the main phase and the crystal boundary epitaxial layer, Dy or Tb does not exist in the main phase, Cu and Dy and/or Tb are distributed on the neodymium-rich phase, and the crystal boundary continuity of the neodymium-iron-boron magnet material is more than 96.5%; more than 95% of the total mass of Ho elements are distributed in the main phase and the crystal boundary epitaxial layer; more than 70% of the total mass of Cu element is distributed in the neodymium-rich phase.

2. Neodymium iron boron magnet material according to claim 1,

the total rare earth content in the neodymium iron boron magnet material is 29.5-32.5 mas%;

and/or the Nd content is 16.2, 21, 21.4, 24, 25.8, 26, or 26.5 mas%;

and/or, when the LR contains Pr, the content of the Pr is 3-7 mas%;

and/or, when the LR comprises Sm, the Sm content is 2.5 mas%;

and/or the Ho content is 0.5-8 mas%;

and/or the content range of Dy and/or Tb is 0.5-0.8 mas%;

when the neodymium iron boron magnet material comprises a mixture of Dy and Tb, the mass ratio of Dy to Tb is 1: (0.01 to 100);

and/or the content range of the Cu is 0.4-0.55 mas%;

and/or the content range of C is 0.07-0.2 mas%;

and/or the content range of Ga is 0.06-0.3 mas%;

and/or the content of Co is 0-0.2 mas%;

and/or the content range of the Al is 0-0.3 mas%;

and/or the content of X is 0.25-0.465 mas%;

and/or X is one or more of Ti, Nb, Zr and Hf;

when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.01-100): 1;

when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.01 to 100);

when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.01-100): 1: (0.01 to 100);

and/or the X also comprises Mn, and the content range of the Mn is 0-0.03 mas%;

and/or the content range of the B is 0.955-0.98 mas%.

3. Neodymium iron boron magnet material according to claim 2,

the total rare earth content in the neodymium iron boron magnet material is 30 mas%, 30.3 mas%, 30.6 mas%, 30.8 mas%, 30.9 mas%, 31.2 mas% or 32 mas%;

and/or, when the LR contains Pr, the content of the Pr is 3-7 mas%;

and/or the Ho content is 1, 2, 4, 4.5 or 6 mas%;

and/or when the neodymium iron boron magnet material comprises Dy, the content of Dy is in the range of 0.2-1 mas%;

and/or when the neodymium iron boron magnet material comprises Tb, the content range of Tb is 0.2-1 mas%;

and/or, when the neodymium iron boron magnet material comprises a mixture of Dy and Tb, the mass ratio of Dy to Tb is 1: (0.3 to 3);

and/or the content of Cu is 0.45mas%, 0.5mas% or 0.52 mas%;

and/or the content of C is 0.098, 0.12, 0.15 or 0.16 mas%;

and/or the content of Ga is 0.07mas%, 0.09mas% or 0.15 mas%;

and/or the content of Co is 0.1 mas%;

and/or the content range of the Al is 0-0.1 mas%;

and/or the content of X is 0.42mas%, 0.43mas% or 0.46 mas%;

and/or, X is Ti and Nb, or Nb and Zr, or Ti, Nb and Zr;

and/or, when the X comprises Zr, the content of Zr is in the range of 0.01-0.3 mas%;

and/or, when the X comprises Ti, the content range of the Ti is 0.1-0.3 mas%;

and/or when the X comprises Nb, the content range of the Nb is 0.04-0.31 mas%;

and/or when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.1-10): 1;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.1 to 10);

and/or when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.1-10): 1: (0.1 to 10);

and/or the content of Mn is 0.01mas%, 0.015mas% or 0.02 mas%;

and/or the content of B is 0.96mas percent or 0.964mas percent.

4. Neodymium iron boron magnet material according to claim 3,

when the LR contains Pr, the content of the Pr is 5 mas%;

and/or, when the neodymium iron boron magnet material comprises Dy, the content of Dy is 0.5mas% or 0.8 mas%;

and/or, when the neodymium iron boron magnet material comprises Tb, the content of Tb is 0.5 mas%;

and/or, when the neodymium iron boron magnet material comprises a mixture of Dy and Tb, the mass ratio of Dy to Tb is 1: 1;

and/or the content of Al is 0.01mas%, 0.02mas%, 0.04mas% or 0.05 mas%;

and/or the content of X is 0.42mas%, 0.43mas% or 0.46 mas%;

and/or, X is Ti and Nb, or Nb and Zr, or Ti, Nb and Zr;

and/or, when said X comprises Zr, said Zr content is 0.1, 0.25 or 0.28 mas%;

and/or, when the X comprises Ti, the Ti content is 0.14mas% or 0.2 mas%;

and/or, when the X comprises Nb, the Nb content is 0.12, 0.15, 0.2, or 0.3 mas%;

and/or, when X comprises Ti and Nb, the mass ratio of Ti to Nb is 1: 2,2:1,2: 3 or 5: 2;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: 0.25, or 1:0.5, or 1: 1.4;

and/or, when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is 1: 2: 1.

5. neodymium iron boron magnet material according to claim 1,

the neodymium iron boron magnet material comprises: nd, 27 mas%; ho, 4.5 mas%; tb, 0.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the balance being Fe;

or, the neodymium iron boron magnet material comprises: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; dy, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the balance being Fe;

or, the neodymium iron boron magnet material comprises: nd, 21.4 mas%; pr, 7.1 mas%; ho, 1 mas%; dy, 0.8 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the balance being Fe;

or, the neodymium iron boron magnet material comprises: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; dy, 0.2 mas%; tb, 0.2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the balance being Fe;

or, the neodymium iron boron magnet material comprises: nd, 25.8 mas%; ho, 4 mas%; tb, 1 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the balance being Fe;

or, the neodymium iron boron magnet material comprises: nd, 26 mas%; ho, 6 mas%; dy, 0.5 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the balance being Fe;

or, the neodymium iron boron magnet material comprises: nd, 16.2 mas%; pr, 5.4 mas%; ho, 8 mas%; dy, 1 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the balance being Fe;

or, the neodymium iron boron magnet material comprises: nd, 21 mas%; ho, 10 mas%; dy, 0.2 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the balance being Fe.

6. A raw material composition of neodymium iron boron magnet material according to any one of claims 1 to 5, comprising a first component and a second component, wherein the first component is an element added during smelting, and the second component is an element added during grain boundary diffusion;

the first component includes:

a light rare earth element LR, wherein LR is Nd; or, the LR comprises Nd, and further comprises Pr and/or Sm; wherein the content of Nd is 16-27 mas%; when the LR contains Pr, the content of the Pr is 0-16 mas% and is not 0 mas%; the addition form of the Pr is Pr and/or PrNd; when the LR contains Sm, the content of the Sm is 0-5 mas percent and is not 0;

Ho，0.5~10mas%；

Cu，0.4~0.6mas%；

C，0~0.32mas%；

ga, 0-0.42 mas%, and is not 0;

Co，0~0.5mas%；

Al，0~0.5mas%；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9~1.05mas%；

the balance being Fe;

the first component does not include other heavy rare earth elements except Ho;

the second component includes: dy and/or Tb 0.2-1 mas%;

and mas% is the mass percentage of each element in the raw material composition of the neodymium iron boron magnet material.

7. A raw material composition of neodymium iron boron magnet material according to claim 6,

the content of Nd is 16.2, 21, 21.4, 24, 25.8, 26 or 26.5 mas%;

and/or, when the LR contains Pr, the content of the Pr is 3-7 mas%;

and/or the addition form of the Pr is PrNd;

and/or, when the LR comprises Sm, the Sm content is 2.5 mas%;

and/or the Ho content is 0.5-8 mas%;

and/or the content range of the Cu is 0.4-0.55 mas%;

and/or the content range of C is 0.07-0.2 mas%;

and/or the content range of Ga is 0.06-0.3 mas%;

and/or the content of Co is 0-0.2 mas%;

and/or the content range of the Al is 0-0.3 mas%;

and/or the content of X is 0.25-0.465 mas%;

and/or X is one or more of Ti, Nb, Zr and Hf;

when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.01-100): 1;

when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.01 to 100);

when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.01-100): 1: (0.01 to 100);

and/or the X also comprises Mn, and the content range of the Mn is 0-0.03 mas%;

and/or the content range of B is 0.955-0.98 mas%;

and/or the content of Dy and/or Tb in the second component is 0.5-0.8 mas%;

and/or when the second component comprises Dy, the content of Dy is in the range of 0.2-1 mas%; the addition form of Dy in the second component is one or more of Dy, Dy alloy and Dy fluoride;

and/or, when the second component comprises Tb, the content range of Tb is 0.2-1 mas%; tb in the second component is added in the form of one or more of Tb, Tb alloy and Tb fluoride;

and/or, when the second component comprises a mixture of Dy and Tb, the mass ratio of Dy to Tb is 1: (0.01 to 100);

and/or the total rare earth content in the raw material composition of the neodymium iron boron magnet material is 29.5-32.5 mas%.

8. A raw material composition of neodymium iron boron magnet material according to claim 7,

the content of Nd is 16.2, 21, 21.4, 24, 25.8, 26 or 26.5 mas%;

and/or, when the LR comprises Pr, the content of Pr is 5 mas%;

and/or, when the LR comprises Sm, the Sm content is 2.5 mas%;

and/or the Ho content is 1, 2, 4, 4.5 or 6 mas%;

and/or the content of Cu is 0.45mas%, 0.5mas% or 0.52 mas%;

and/or the content of C is 0.098, 0.12, 0.15 or 0.16 mas%;

and/or the content of Ga is 0.07mas%, 0.09mas% or 0.15 mas%;

and/or the content of Co is 0.1 mas%;

and/or the content range of the Al is 0-0.1 mas%;

and/or the content of X is 0.42mas%, 0.43mas% or 0.46 mas%;

and/or, X is Ti and Nb, or Nb and Zr, or Ti, Nb and Zr;

and/or, when the X comprises Zr, the content of Zr is in the range of 0.01-0.3 mas%;

and/or, when the X comprises Ti, the content range of the Ti is 0.1-0.3 mas%;

and/or when the X comprises Nb, the content range of the Nb is 0.04-0.31 mas%;

and/or when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.1-10): 1;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.1 to 10);

and/or when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.1-10): 1: (0.1 to 10);

and/or the content of Mn is 0.01mas%, 0.015mas% or 0.02 mas%;

and/or the content of B is 0.96mas% or 0.964 mas%;

and/or, when the second component comprises Dy, the content of Dy is 0.5mas% or 0.8 mas%;

and/or the Dy alloy is DyGaCu; in the DyGaCu alloy, the Dy content is more than or equal to 75mas percent, and the percentage is the percentage of the Dy mass in the total mass of the DyGaCu alloy;

and/or, when the second component comprises Tb, the content of Tb is 0.5 mas%;

and/or the Tb alloy is a TbGaCu alloy; in the TbGaCu alloy, the Tb content is more than or equal to 75mas percent, and the percentages are the percentages of Tb consumption in the total mass of the TbGaCu alloy;

and/or, when the second component comprises a mixture of Dy and Tb, the mass ratio of Dy to Tb is 1: (0.3 to 3);

and/or the total rare earth content in the raw material composition of the neodymium iron boron magnet material is 30 mas%, 30.3 mas%, 30.6 mas%, 30.8 mas%, 30.9 mas%, 31.2 mas% or 32 mas%.

9. A raw material composition of neodymium-iron-boron magnet material according to claim 8,

the content of the Al is 0.01mas%, 0.02mas%, 0.04mas% or 0.05 mas%;

and/or, when said X comprises Zr, said Zr content is 0.1, 0.25 or 0.28 mas%;

and/or, when the X comprises Ti, the Ti content is 0.14mas% or 0.2 mas%;

and/or, when the X comprises Nb, the Nb content is 0.12, 0.15, 0.2, or 0.3 mas%;

and/or, when X comprises Ti and Nb, the mass ratio of Ti to Nb is 1: 2,2:1,2: 3 or 5: 2;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: 0.25, or 1:0.5, or 1: 1.4;

and/or, when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is 1: 2: 1;

and/or the Dy alloy is DyGaCu; in the DyGaCu alloy, the Dy content is more than or equal to 95mas percent, and the percentage is the percentage of the Dy mass in the total mass of the DyGaCu alloy;

and/or the Tb alloy is a TbGaCu alloy; in the TbGaCu alloy, the Tb content is more than or equal to 95mas percent, and the percentages are the percentages of Tb consumption in the total mass of the TbGaCu alloy;

and/or, when the second component comprises a mixture of Dy and Tb, the mass ratio of Dy to Tb is 1:1.

10. a raw material composition of neodymium iron boron magnet material according to claim 6,

the raw material composition of the neodymium iron boron magnet material comprises: the first component: nd, 27 mas%; ho, 4.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the second component: tb, 0.5 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron magnet material comprises: the first component: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the second component: dy, 0.5 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron magnet material comprises: the first component: PrNd, 28.5 mas%; ho, 1 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the second component: dy, 0.8 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron magnet material comprises: the first component: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the second component: dy, 0.2 mas%; tb, 0.2 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron magnet material comprises: the first component: nd, 25.8 mas%; ho, 4 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the second component: tb, 1 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron magnet material comprises: the first component: nd, 26 mas%; ho, 6 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the second component: dy, 0.5 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron magnet material comprises: the first component: PrNd, 21.6 mas%; ho, 8 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the second component: dy, 1 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron magnet material comprises: the first component: nd, 21 mas%; ho, 10 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the second component: dy, 0.2 mas%; the balance being Fe.

11. A method of manufacturing a neodymium iron boron magnet material according to any one of claims 1 to 5, which is performed using a raw material composition of the neodymium iron boron magnet material according to any one of claims 6 to 10, the method comprising the steps of:

s1, smelting, pulverizing, molding and sintering the first component to obtain a neodymium iron boron sintered body;

s2, performing grain boundary diffusion on the neodymium iron boron sintered body obtained in the step S1 by adopting the second component;

and S3, carrying out heat treatment to obtain the neodymium iron boron magnet material.

12. The method of manufacturing a neodymium-iron-boron magnet material according to claim 11,

in step S1, the smelting operation and conditions are to perform smelting casting on each element of the first component by using an ingot casting process or a rapid hardening sheet process to obtain an alloy sheet;

and/or in the step S1, the smelting temperature is 1300-1700 ℃;

and/or in step S1, the smelting equipment is a high-frequency vacuum smelting furnace and/or a medium-frequency vacuum smelting furnace;

and/or in step S1, the operation and conditions of the milling include hydrogen milling and/or airflow milling; wherein the content of the first and second substances,

the hydrogen crushing powder comprises hydrogen absorption, dehydrogenation and cooling treatment;

the gas flow in the gas flow milling powder is nitrogen and/or argon; the pressure of the airflow milling powder is 0.1-2 MPa;

and/or, in step S1, the operation and condition of the forming is a magnetic field forming method;

and/or, in the step S1, the sintering operation and conditions are a vacuum sintering process and/or an inert atmosphere sintering process;

and/or in the step S1, the sintering temperature is 1000-1200 ℃;

and/or in the step S1, the sintering time is 0.5-10 h;

and/or in step S2, the operation and condition of grain boundary diffusion is to apply the second component to the sintered nd-fe-b body and keep the temperature, wherein the application mode is coating, magnetron plasma sputtering or evaporation; the temperature of the grain boundary diffusion is 800-1000 ℃;

and/or in the step S2, the time of grain boundary diffusion is 12-90 h;

and/or in step S3, the temperature of the heat treatment is 480-510 ℃; the time of the heat treatment is 2-4 hours.

13. The method of manufacturing a neodymium-iron-boron magnet material according to claim 12,

in step S1, the smelting temperature is 1500 ℃;

and/or the medium-frequency vacuum smelting furnace is a medium-frequency vacuum induction rapid hardening melt-spinning furnace;

and/or the temperature of hydrogen absorption is 20-200 ℃;

and/or the pressure of hydrogen absorption is 50-600 kPa;

and/or the dehydrogenation temperature is 400-650 ℃;

and/or the pressure of the airflow milled powder is 0.5-0.7 MPa;

and/or the efficiency of the airflow milling powder is 30-400 kg/h;

and/or the magnetic field intensity of the magnetic field forming method is more than 1.5T;

and/or in the step S1, the sintering temperature is 1030-1090 ℃;

and/or in the step S1, the sintering time is 2-8 h;

and/or in the step S2, the temperature of the grain boundary diffusion is 850-950 ℃;

and/or in step S2, the time of grain boundary diffusion is 24 h.

14. The method of manufacturing a neodymium-iron-boron magnet material according to claim 13,

the temperature of hydrogen absorption is 20-40 ℃;

and/or the pressure of hydrogen absorption is 90 kPa;

and/or the temperature of the dehydrogenation is 550 ℃;

and/or the pressure of the airflow milled powder is 0.65 MPa;

and/or the efficiency of the airflow milling powder is 200 kg/h;

and/or in step S2, the temperature of the grain boundary diffusion is 900 ℃.

15. A neodymium iron boron magnet material prepared according to the method for preparing a neodymium iron boron magnet material of any one of claims 11 to 14.

16. A neodymium iron boron sintered body for preparing the neodymium iron boron magnet material defined in any one of claims 1-5, comprising:

a light rare earth element LR, wherein LR is Nd; or, the LR comprises Nd, and further comprises Pr and/or Sm; wherein the content of Nd is 16-27 mas%; when the LR contains Pr, the content of the Pr is 0-16 mas% and is not 0 mas%; when the LR contains Sm, the content of the Sm is 0-5 mas percent and is not 0;

Ho，0.5~10mas%；

Cu，0.4~0.6mas%；

C，0~0.32mas%；

ga, 0-0.42 mas%, and is not 0;

Co，0~0.5mas%；

Al，0~0.5mas%；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9~1.05mas%；

the neodymium iron boron sintered body does not contain other heavy rare earth elements except Ho;

the balance being Fe;

mas% is the mass percentage of each element in the neodymium iron boron sintered body;

the microstructure of the neodymium iron boron sintered body comprises a main phase, a grain boundary epitaxial layer and a neodymium-rich phase; ho is distributed on the main phase and the crystal boundary epitaxial layer, Cu is distributed on the neodymium-rich phase, and the continuity of the crystal boundary of the neodymium-iron-boron sintered body is more than 96%.

17. The sintered body of neodymium iron boron according to claim 16,

the total rare earth content in the neodymium iron boron sintered body is 28.5-32.3 mas%;

and/or the Nd content is 16.2, 21, 21.4, 24, 25.8, 26, or 26.5 mas%;

and/or, when the LR contains Pr, the content of the Pr is 3-7 mas%;

and/or, when the LR comprises Sm, the Sm content is 2.5 mas%;

and/or the Ho content is 0.5-8 mas%;

and/or the content range of the Cu is 0.4-0.55 mas%;

and/or the content range of C is 0.07-0.2 mas%;

and/or the content range of Ga is 0.06-0.3 mas%;

and/or the content of Co is 0-0.2 mas%;

and/or the content range of the Al is 0-0.3 mas%;

and/or the content of X is 0.25-0.465 mas%;

and/or X is one or more of Ti, Nb, Zr and Hf;

when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.01-100): 1;

when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.01 to 100);

when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.01-100): 1: (0.01 to 100);

and/or the X also comprises Mn, and the content range of the Mn is 0-0.03 mas%;

and/or the content range of the B is 0.955-0.98 mas%.

18. The sintered body of neodymium iron boron according to claim 17,

the total rare earth content in the neodymium iron boron sintered body is 29.5 mas%, 29.6 mas%, 29.8mas%, 30.5 mas%, 31mas%, 31.5 mas% or 32 mas%;

and/or, when the LR contains Pr, the content of the Pr is 3-7 mas%;

and/or the Ho content is 1, 2, 4, 4.5 or 6 mas%;

and/or the content range of the Cu is 0.45mas%, 0.5mas% or 0.52 mas%;

and/or the content of C is 0.098, 0.12, 0.15 or 0.16 mas%;

and/or the content of Ga is 0.07mas%, 0.09mas%, 0.15 mas%;

and/or the content of Co is 0.1 mas%;

and/or the content range of the Al is 0-0.1 mas%;

and/or the content of X is 0.42mas%, 0.43mas% or 0.46 mas%;

and/or, X is Ti and Nb, or Nb and Zr, or Ti, Nb and Zr;

and/or, when the X comprises Zr, the content of Zr is in the range of 0.01-0.3 mas%;

and/or, when the X comprises Ti, the content range of the Ti is 0.1-0.3 mas%;

and/or when the X comprises Nb, the content range of the Nb is 0.04-0.31 mas%;

and/or when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.1-10): 1;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.1 to 10);

and/or when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.1-10): 1: (0.1 to 10);

and/or the content of Mn is 0.01mas%, 0.015mas% or 0.02 mas%;

and/or the content of B is 0.96mas percent or 0.964mas percent.

19. The sintered body of neodymium iron boron according to claim 18,

when the LR contains Pr, the content of the Pr is 5 mas%;

and/or the content of Al is 0.01mas%, 0.02mas%, 0.04mas% or 0.05 mas%;

and/or, when said X comprises Zr, said Zr content is 0.1, 0.25 or 0.28 mas%;

and/or, when the X comprises Ti, the Ti content is 0.14mas% or 0.2 mas%;

and/or, when the X comprises Nb, the Nb content is 0.12, 0.15, 0.2, or 0.3 mas%;

and/or, when X comprises Ti and Nb, the mass ratio of Ti to Nb is 1: 2,2:1,2: 3 or 5: 2;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: 0.25, or 1:0.5, or 1: 1.4;

and/or, when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is 1: 2: 1.

20. the sintered body of neodymium iron boron according to claim 16,

the neodymium iron boron sintered body comprises: nd, 27 mas%; ho, 4.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the balance being Fe;

or, the neodymium iron boron sintered body comprises: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the balance being Fe;

or, the neodymium iron boron sintered body comprises: nd, 21.4 mas%; pr, 7.1 mas%; ho, 1 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the balance being Fe;

or, the neodymium iron boron sintered body comprises: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the balance being Fe;

or, the neodymium iron boron sintered body comprises: nd, 25.8 mas%; ho, 4 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the balance being Fe;

or, the neodymium iron boron sintered body comprises: nd, 26 mas%; ho, 6 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the balance being Fe;

or, the neodymium iron boron sintered body comprises: nd, 16.2 mas%; pr, 5.4 mas%; ho, 8 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the balance being Fe;

or, the neodymium iron boron sintered body comprises: nd, 21 mas%; ho, 10 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the balance being Fe.

21. A raw material composition of a neodymium iron boron sintered body according to any one of claims 16 to 20, comprising:

a light rare earth element LR, wherein LR is Nd; or, the LR comprises Nd, and further comprises Pr and/or Sm; wherein the content of Nd is 16-27 mas%; when the LR contains Pr, the content of the Pr is 0-16 mas% and is not 0 mas%; the addition form of the Pr is Pr and/or PrNd; when the LR contains Sm, the content of the Sm is 0-5 mas percent and is not 0;

Ho，0.5~10mas%；

Cu，0.4~0.6mas%；

C，0~0.32mas%；

ga, 0-0.42 mas%, and is not 0;

Co，0~0.5mas%；

Al，0~0.5mas%；

x, 0.05-0.5 mas%; the X comprises one or more of Ti, Nb, Zr, Hf, V, Mo, W, Ta and Cr;

B，0.9~1.05mas%；

the raw material composition of the neodymium iron boron sintered body does not contain other heavy rare earth elements except Ho;

the balance being Fe;

and mas percent is the mass percentage of each element in the raw material composition of the neodymium iron boron sintered body.

22. The raw material composition of neodymium iron boron sintered body according to claim 21,

the total rare earth content in the raw material composition of the neodymium iron boron sintered body is 28.5-32.3 mas%;

and/or the Nd content is 16.2, 21, 21.4, 24, 25.8, 26, or 26.5 mas%;

and/or, when the LR contains Pr, the content of the Pr is 3-7 mas%;

and/or the addition form of the Pr is PrNd;

and/or, when the LR comprises Sm, the Sm content is 2.5 mas%;

and/or the Ho content is 0.5-8 mas%;

and/or the content range of the Cu is 0.4-0.55 mas%;

and/or the content range of C is 0.07-0.2 mas%;

and/or the content range of Ga is 0.06-0.3 mas%;

and/or the content of Co is 0-0.2 mas%;

and/or the content range of the Al is 0-0.3 mas%;

and/or the content of X is 0.25-0.465 mas%;

and/or X is one or more of Ti, Nb, Zr and Hf;

when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.01-100): 1;

when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.01 to 100);

when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.01-100): 1: (0.01 to 100);

and/or the X also comprises Mn, and the content range of the Mn is 0-0.03 mas%;

and/or the content range of the B is 0.955-0.98 mas%.

23. The raw material composition of neodymium iron boron sintered body according to claim 22,

the total rare earth content in the raw material composition of the neodymium iron boron sintered body is 29.5 mas%, 29.6 mas%, 29.8mas%, 30.5 mas%, 31mas%, 31.5 mas% or 32 mas%;

and/or, when the LR comprises Pr, the content of Pr is 5 mas%;

and/or the Ho content is 1, 2, 4, 4.5 or 6 mas%;

and/or the content of Cu is 0.45mas%, 0.5mas% or 0.52 mas%;

and/or the content of C is 0.098, 0.12, 0.15 or 0.16 mas%;

and/or the content of Ga is 0.07mas%, 0.09mas%, 0.15 mas%;

and/or the content of Co is 0.1 mas%;

and/or the content range of the Al is 0-0.1 mas%;

and/or the content of X is 0.42mas%, 0.43mas% or 0.46 mas%;

and/or, X is Ti and Nb, or Nb and Zr, or Ti, Nb and Zr;

and/or when X comprises Ti and Nb, the mass ratio of Ti to Nb is (0.1-10): 1;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: (0.1 to 10);

and/or when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is (0.1-10): 1: (0.1 to 10);

and/or the content of Mn is 0.01mas%, 0.015mas% or 0.02 mas%;

and/or the content of B is 0.96mas percent or 0.964mas percent.

24. The raw material composition of neodymium iron boron sintered body according to claim 23,

the content of the Al is 0.01mas%, 0.02mas%, 0.04mas% or 0.05 mas%;

and/or, when X comprises Ti and Nb, the mass ratio of Ti to Nb is 1: 2,2:1,2: 3 or 5: 2;

and/or, when X comprises Nb and Zr, the mass ratio of Nb to Zr is 1: 0.25, or 1:0.5, or 1: 1.4;

and/or, when X comprises Ti, Nb and Zr, the mass ratio of Ti, Nb and Zr is 1: 2: 1.

25. the raw material composition of neodymium iron boron sintered body according to claim 21,

the raw material composition of the neodymium iron boron sintered body comprises: nd, 27 mas%; ho, 4.5 mas%; cu, 0.52 mas%; c, 0.07 mas%; ga, 0.15 mas%; ti, 0.3 mas%; nb, 0.12 mas%; b, 0.96 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron sintered body comprises: nd, 26.5 mas%; sm, 2.5 mas%; ho, 0.5 mas%; cu, 0.5 mas%; c, 0.16 mas%; ga, 0.2 mas%; zr, 0.25 mas%; b, 0.96 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron sintered body comprises: PrNd, 28.5 mas%; ho, 1 mas%; cu, 0.4 mas%; ga, 0.42 mas%; al, 0.05 mas%; ti, 0.14 mas%; nb, 0.31 mas%; mn, 0.01 mas%; b, 0.98 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron sintered body comprises: nd, 24 mas%; pr, 4.5 mas%; ho, 2 mas%; cu, 0.4 mas%; c, 0.15 mas%; ga, 0.09 mas%; al, 0.01 mas%; ti, 0.1 mas%; nb, 0.2 mas%; zr, 0.2 mas%; mn, 0.03 mas%; b, 0.98 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron sintered body comprises: nd, 25.8 mas%; ho, 4 mas%; cu, 0.55 mas%; c, 0.098 mas%; ga, 0.24 mas%; ti, 0.2 mas%; nb, 0.3 mas%; b, 0.955 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron sintered body comprises: nd, 26 mas%; ho, 6 mas%; cu, 0.55 mas%; c, 0.2 mas%; ga, 0.07 mas%; al, 0.04 mas%; co, 0.1 mas%; nb, 0.04 mas%; zr, 0.01 mas%; b, 0.955 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron sintered body comprises: PrNd, 21.6 mas%; ho, 8 mas%; cu, 0.6 mas%; c, 0.12 mas%; ga, 0.3 mas%; al, 0.1 mas%; ti, 0.3 mas%; nb, 0.15 mas%; b, 0.964 mas%; the balance being Fe;

or, the raw material composition of the neodymium iron boron sintered body comprises: nd, 21 mas%; ho, 10 mas%; cu, 0.6 mas%; c, 0.32 mas%; ga, 0.06 mas%; al, 0.02 mas%; co, 0.2 mas%; nb, 0.2 mas%; zr, 0.28 mas%; mn, 0.02 mas%; b, 0.964 mas%; the balance being Fe.

26. A method of manufacturing a neodymium iron boron sintered body according to any one of claims 16 to 20, comprising: the neodymium iron boron sintered body raw material composition is prepared by smelting, pulverizing, molding and sintering the raw material composition of the neodymium iron boron sintered body according to any one of claims 21 to 25; the smelting, milling, forming and sintering are as defined in any one of claims 11-14.

27. A neodymium iron boron sintered body prepared according to the method of preparing a neodymium iron boron sintered body of claim 26.

28. Use of a neodymium iron boron magnet material according to any one of claims 1 to 5 and 15 or a neodymium iron boron sintered body according to claims 16 to 20 and 27 in the preparation of magnetic steel.

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