WO2020155283A1 - High-entropy alloy boride ceramic, and preparation method therefor and application thereof - Google Patents

Abstract

A high-entropy alloy boride ceramic and a preparation method therefor. The molecular formula of the high-entropy alloy boride ceramic is Aly(FeNiCoCr)1-x-yBx, wherein 0≤x≤1 and 0≤y≤1.The high-entropy alloy boride is prepared by the following steps: carrying out ball milling on Al, Fe, Ni, Co, Cr, and B to prepare Aly(FeNiCoCr)1-x-yBx powder; then carrying out spark plasma sintering at a heating rate of 50-200 °C/min, a temperature of 800-1500 °C, and a constant pressure of 10-50 Mpa; carrying out furnace cooling. The Aly(FeNiCoCr)1-x-yBx high-entropy alloy boride powder prepared by the method is approximately spherical and is small in particle size, the ceramic main phase is an FCC solid solution in which Fe and Cr metal borides are dispersed, and high density, high hardness and wear resistance are achieved.

Description

High-entropy alloy boride ceramic and preparation method and application thereof Technical field

The invention belongs to the technical field of boride ceramic materials, and more specifically, relates to a high-entropy alloy boride ceramic (Al _y (FeNiCoCr) _1-xy B _x , 0≤x≤1, 0≤y≤1) and its preparation Methods and applications.

Background technique

At the end of the last century, the concept of high-entropy series materials was proposed, which consisted of 5 or more elements, and the atomic percentage of each element was between 5% and 35%. The structure was simple, mostly BCC phase, FCC phase or BCC+FCC Two-phase structure. The alloy components are highly disordered and the structure is simple. Most of them are BCC, FCC or BCC+FCC dual-phase structure. The high entropy effect effectively inhibits the production of intermetallic compounds.

In recent years, high-entropy materials have been widely studied by domestic and foreign scholars because of their high strength, high hardness, wear resistance, corrosion resistance and high temperature softening resistance. The reported literature on high-entropy materials is mainly prepared by vacuum melting and casting methods. The size of the blocks prepared is small, and because the materials used, such as nickel, cobalt, chromium, etc., are relatively expensive, the cost of the prepared materials is high. Since Cantor et al. first reported the FeCrNiCoMn alloy with a single structure in 2004, the alloy has received widespread attention. FeCrNiCoMn alloy has a simple fcc solid solution structure, and it can still exist stably after being kept at 1100℃ for 6h. The alloy also has very good forging characteristics and low temperature yield strength. Although the alloy has these excellent properties, the alloy is dominated by fcc structure solid solution and has a low hardness, which greatly limits the life and range of its use as a surface material.

At present, high-entropy series materials are mainly prepared by arc smelting. In order to make the distribution of various elements uniform, the alloy ingots need to be smelted many times. The process is complicated and it is difficult to prepare large-size and complex-shaped samples. Affected by the cooling of the arc smelting water-cooled copper crucible, the ingot is prone to dendrite segregation, composition segregation and the formation of coarse dendrites and columnar crystal structures. Powder metallurgy and surface coating technology provide a new development direction for the research of this type of alloy. Powder metallurgy can effectively avoid component segregation and refine grains. The prepared alloy has good structure and component uniformity;

The mechanical alloying method can effectively overcome the problems of the vacuum arc smelting method, and can prepare high-entropy alloys with good chemical homogeneity, fine crystal grains and even nanocrystalline, and can also prepare ceramic high-entropy alloy composite materials. The disadvantage of the mechanical alloy method is that the ball milling process, the ball milling medium, the atmosphere in the spherical tank, and the process control agent may contaminate the raw materials. Therefore, in the process of preparing high-entropy alloy powder and sintering, it is necessary to strictly control and reduce the pollution to the powder. Ball milling causes work hardening and amorphous crystallization, which significantly increases the hardness of the alloy powder after ball milling.

Boron is an important alloy element in metal materials. As a solid solution atom, boron can often greatly improve the hardness and wear resistance of the solid solution. Studies have shown that the introduction of boron into the alloy will generate a hard second phase of metal boride, which can significantly improve the mechanical properties of the alloy. The results of studies on boron-containing alloy blocks have shown that boron mainly exists in the form of solid solution and boride precipitates in high-entropy alloys. Now the AlFeNiCoCr high-entropy alloy is added with boron element, the boron element is solid-dissolved between the alloy elements by mechanochemical method, the lattice distortion effect of the high-entropy alloy is strengthened by high-energy ball milling, and the solid solution of B element and other elements is emphasized. High-entropy alloy block is prepared by spark plasma sintering, hot pressing sintering, and air pressure sintering to reduce the precipitation of intermetallic compounds, and by changing the content of boron element, to strengthen the hardness and increase the hardness of AlFeNiCoCrB _x high-entropy alloy boride block Abrasion resistance.

Summary of the invention

In order to solve the above-mentioned shortcomings and shortcomings of the prior art, the present invention provides an Al _y (FeNiCoCr) _1-xy B _x (0≤x≤1, 0≤y≤1) high-entropy alloy boride ceramic. The ceramic has high hardness and good wear resistance.

Another object of the present invention is to provide a method for preparing the above-mentioned Al _y (FeNiCoCr) _1-xy B _x high-entropy alloy boride ceramics. Through mechanochemical method and spark plasma sintering, the microstructure is a high-entropy material with metal borides dispersed in the FCC solid solution matrix, and by changing the Al _y (FeNiCoCr) _1-xy B _x high-entropy alloy B element and Al element The mole percentage is used to adjust the volume fraction of the FCC solid solution phase and the metal boride phase to obtain high-entropy boride ceramics with higher hardness and good wear resistance.

Another object of the present invention is to provide applications of the above-mentioned high-entropy alloy boride ceramics.

The purpose of the present invention is achieved through the following technical solutions:

A high-entropy alloy boride ceramic, the molecular formula of the high-entropy alloy boride ceramic is Al _y (FeNiCoCr) _1-xy B _x , wherein 0≤x≤1, 0≤y≤1, the high-entropy alloy boron The compound is made by ball milling Al, Fe, Ni, Co, Cr and B by mechanochemical method to obtain Al _y (FeNiCoCr) _1-xy B _x powder; and then at a constant pressure of 10-50Mpa, at a heating rate of 50-200 ℃/min, sintering at 800-1500℃ (sintering method can be spark plasma sintering, hot pressing sintering or air pressure sintering), and finally made by furnace cooling.

Preferably, the purity of the Al, Fe, Ni, Co, Cr and B powders are all 99.95-99.99 wt.%.

The preparation method of the high-entropy alloy boride ceramic includes the following specific steps:

S1. In an argon atmosphere, the Al, Fe, Ni, Co, Cr, B powders are mixed according to the proportions, mixed and evenly placed in a high-energy ball mill for ball milling, and high-entropy alloy boride powder is obtained after ball milling;

S2. Take out the ball-milled powder, dry and sieving to obtain the high-entropy alloy boride powder that has been solid-solved;

S3. Put the powder into the spark plasma sintering mold and perform pre-compression, and sinter under the protection of Ar atmosphere. The sintering process parameters are: heating rate 50～200℃/min, sintering temperature 800～1500℃ and heat preservation, constant pressure 10～50Mpa, and finally cooled with the furnace to obtain high-entropy alloy boride ceramics.

Preferably, the rotation speed of the ball mill in step S1 is 300-1425 rpm, the ball-to-material ratio is (2-20):1, and the time of the ball mill is 5-200 h.

Preferably, the particle size of the high-entropy alloy boride powder in step S1 is 5 to 45 μm.

Preferably, the sintering time in step S3 is 5-30 min.

The application of the high-entropy alloy boride ceramics in the tool field.

Compared with the prior art, the present invention has the following beneficial effects:

The invention uses mechanochemical method combined with spark plasma sintering (hot press sintering or air pressure sintering) to obtain high-entropy alloy boride ceramics with uniform structure, not easy to segregate, and fine crystal grains, and a microstructure is obtained with FCC solid solution as the matrix and dispersed distribution Fe, Cr boride Al _y (FeNiCoCr) _1-xy B _x high-entropy alloy boride to strengthen Al _y (FeNiCoCr) _1-xy B _x (0≤x≤1, 0≤y≤1) Entropy alloy boride block hardness and improve wear resistance.

Description of the drawings

1A and 1B are SEM pictures of Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride powder prepared in Example 1 under different magnifications.

2 is the XRD pattern of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1.

3 is an SEM photograph of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1.

4 is a metallographic micrograph of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1.

5 is an SEM photograph of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1 under a 10Kg load of a Vickers hardness tester.

6 is an SEM photograph of the wear scar of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1 under a load of 5N and a friction and wear distance of 200 m.

7 is the XRD pattern of the Al _0.2 (FeNiCoCr) _0.6 B _0.2 high-entropy alloy boride block prepared in Example 2.

8 is an SEM photograph of the wear scar of the Al _0.2 (FeNiCoCr) _0.6 B _0.2 high-entropy alloy boride block prepared in Example 2 under a load of 5N and a friction and wear distance of 200 m.

9 is an XRD pattern of the Al _0.25 (FeNiCoCr) _0.25 B _0.25 high-entropy alloy boride block prepared in Example 3.

10 is an XRD pattern of the Al _0.5 (FeNiCoCr) _0.5 high-entropy alloy boride block prepared in Example 4.

11 is an SEM photograph of the Al _0.5 (FeNiCoCr) _0.5 high-entropy alloy boride block prepared in Example 4.

Figure 12 is the hardness change curve of the Al _y (FeNiCoCr) _1-xy B _x high-entropy alloy boride block prepared in Examples 1-4 under different loads.

13 is an SEM photograph of the wear scar of the Al _0.5 (FeNiCoCr) _0.5 high-entropy alloy boride block prepared in Example 4 under a load of 5N and a friction and wear distance of 200 m.

detailed description

The content of the present invention is further described below in conjunction with specific embodiments, but it should not be understood as a limitation to the present invention. Unless otherwise specified, the technical means used in the embodiments are conventional means well known to those skilled in the art. Unless otherwise specified, the reagents, methods and equipment used in the present invention are conventional reagents, methods and equipment in the technical field.

In the embodiment of the present invention, the powder preparation process is protected by argon in the whole process, and a high-energy ball mill model of 8000M from SPEX of the United States is used for powder synthesis. There are a total of six tungsten carbide grinding balls with a size of 11.20mm, and the mass ratio of the balls to the mixed powder is 4:1.

Example 1

A kind of Al _y (FeNiCoCr) _1-xy B _x (x＝1/3, y＝1/3) high-entropy alloy boride powder. The high-entropy alloy boride powder consists of Al, Fe, Ni, Co, Cr and B Element composition, the molar ratio of the content of each element is Al:Fe:Ni:Co:Cr:B=1:1:1:1:1:1:1. After being put into the ball milling tank, the powder is ball milled for 200 hours according to the design process parameters of the ball mill.

Secondly, the high-entropy alloy boride powder after ball milling is put into the spark plasma sintering mold for sintering. The sintering process parameters are: heating rate 100℃/min, sintering temperature 1100℃, holding time 10min, constant pressure 30Mpa, to obtain Al _{1 /3} (FeNiCoCr) _1/3 B _1/3 ceramic.

Fig. 1 is SEM pictures of Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride powder prepared in Example 1 under different magnifications. Among them, 1A is 500 times magnification, and 1B is 4000 times magnification. It can be seen from Figure 1 that the particle morphology of the powder after ball milling is spherical or approximately spherical with uniform particle size, with a particle size range of 5 to 45 μm. 2 is the XRD pattern of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1. It can be seen from Figure 2 that borides are formed. Figure 3 is an SEM photograph of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in this embodiment. Among them, (a) is the SEM image of Al _1/3 (FeNiCoCr) _1/3 B _1/3 cross-section, (b) is the SEM image of the corroded surface of Al _1/3 (FeNiCoCr) _1/3 B _1/3 , and the etching solution is configured The molar ratio is HCl:FeCl3:H2O= ₁ : ₁ : ₁₀ . It can be seen from Fig. 3 that Fe, Cr, and B are enriched in the network structure area to form borides. 5 is an SEM photograph of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1 under a 10Kg load of a Vickers hardness tester. 6 is an SEM photograph of the wear scar of the Al _1/3 (FeNiCoCr) _1/3 B _1/3 high-entropy alloy boride block prepared in Example 1 under a load of 5N and a friction and wear distance of 200 m. The Vickers hardness under a load of 20Kg is 1195.2Hv; the fracture toughness measured by the indentation method is 4.42Mpa·m ^1/2 .

Example 2

A kind of Al _y (FeNiCoCr) _1-xy B _x (x=1/5, y=2/5) high-entropy alloy boride powder, the high-entropy alloy powder is composed of Al, Fe, Ni, Co, Cr and B, The molar ratio of the content of each element is Al:Fe:Ni:Co:Cr:B=1:1:1:1:1:1:0.5. After being put into the ball milling tank, ball milling is carried out for 60 hours according to the design process parameters of the ball mill. The particle morphology is spherical or nearly spherical with uniform particle size, and the particle size ranges from 5 to 45 μm.

Secondly, the ball-milled high-entropy alloy boride powder is put into a spark plasma sintering mold for sintering. The sintering process parameters are: heating rate 100℃/min, sintering temperature 1100℃, holding time 10min, constant pressure 30Mpa, to obtain Al _0.2 (FeNiCoCr) _0.6 B _0.2 ceramic.

7 is the XRD pattern of the Al _0.2 (FeNiCoCr) _0.6 B _0.2 high-entropy alloy boride block prepared in Example 2. As shown in Figure 7, the amount of boride generated is small; Figure 8 is the SEM photo of the wear scar of the Al _0.2 (FeNiCoCr) _0.6 B _0.2 high-entropy alloy boride block prepared in Example 2 under a load of 5N and a friction and wear distance of 200m . After sintering, the Vickers hardness of the block under a load of 20Kg is 804.1Hv; the fracture toughness measured by the indentation method is 5.13Mpa·m ^1/2 .

Example 3

A kind of Al _y (FeNiCoCr) _1-xy B _x (x=1/2, y=1/4) high-entropy alloy boride powder. The high-entropy alloy boride powder consists of Al, Fe, Ni, Co, Cr and B Composition, the molar ratio of the content of each element is Al:Fe:Ni:Co:Cr:B=1:1:1:1:1:1:2. After being put into the ball milling tank, ball milling is carried out for 60 hours according to the design process parameters of the ball mill. The particle morphology is spherical or nearly spherical with uniform particle size, and the particle size ranges from 5 to 45 μm.

Secondly, the ball-milled high-entropy alloy boride powder is put into a spark plasma sintering mold for sintering. The sintering process parameters are: heating rate 100℃/min, sintering temperature 1100℃, holding time 10min, constant pressure 30Mpa, and Al _{0.25 is obtained.} (FeNiCoCr) _0.25 B _0.25 ceramic. 9 is an XRD pattern of the Al _0.25 (FeNiCoCr) _0.25 B _0.25 high-entropy alloy boride block prepared in Example 3. As shown in Figure 9, the amount of boride is large; the Vickers hardness of the block after sintering is 1044.0Hv under a load of 20Kg; the fracture toughness measured by the indentation method is 5.13Mpa·m ^1/2 .

Example 4

A kind of Al _y (FeNiCoCr) _1-xy B _x (x=0, y=1/2) high-entropy alloy boride powder, high-entropy alloy powder is composed of six elements: Al, Fe, Ni, Co, Cr and B , The molar ratio of the content of each element is Al:Fe:Ni:Co:Cr:B=1:1:1:1:1:1:0. After being put into the ball milling tank, ball milling is carried out for 60 hours according to the design process parameters of the ball mill. The SEM image of the powder after ball milling is shown in the figure. The particle morphology is spherical or nearly spherical with uniform particle size, and the particle size ranges from 5-45μm.

Secondly, the high-entropy boride powder after ball milling is put into the spark plasma sintering mold for sintering. The sintering process parameters are: heating rate 100℃/min, sintering temperature 1100℃, holding time 10min, constant pressure 30Mpa, and Al _0.5 ( FeNiCoCr) _0.5 ceramic.

10 is an XRD pattern of the Al _0.5 (FeNiCoCr) _0.5 high-entropy alloy boride block prepared in Example 4. As shown in FIG. 10, there is no boride. FIG. 11 is an SEM photograph of the Al _0.5 (FeNiCoCr) _0.5 high-entropy alloy boride block prepared in Example 4. Figure 12 is the hardness change curve of the Al _y (FeNiCoCr) _1-xy B _x high-entropy alloy boride block prepared in Examples 1-4 under different loads. Among them, the curves a, b, c, and d are the hardness of Examples 1-4, respectively. The hardness of the sample of Example 1 is nearly doubled that of Example 4, indicating that the addition of B can effectively increase the hardness; in the sample hardness of Example 1 highest. 13 is an SEM photograph of the wear scar of the Al _0.5 (FeNiCoCr) _0.5 high-entropy alloy boride block prepared in Example 4 under a load of 5N and a friction and wear distance of 200 m. Figure 13 shows that the wear scar width of the Al _0.5 (FeNiCoCr) _0.5 high-entropy alloy boride block is large, and the sample is not wear-resistant without B. The Vickers hardness of the sintered block under a load of 20Kg is 557.6Hv.

The above-mentioned embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above-mentioned embodiments, and any other changes, modifications, substitutions, combinations and combinations made without departing from the spirit and principle of the present invention Simplified, all should be equivalent replacement methods, and all are included in the protection scope of the present invention.

Claims (8)

1. A high-entropy alloy boride ceramic, characterized in that the molecular formula of the high-entropy alloy boride ceramic is Al _y (FeNiCoCr) _1-xy B _x , where 0≤x≤1, 0≤y≤1, High-entropy alloy boride is made by ball milling Al, Fe, Ni, Co, Cr and B by mechanochemical method to produce Al _y (FeNiCoCr) _1-xy B _x powder; the above powder is protected by Ar atmosphere, Constant pressure 10～50Mpa, heating rate 50～200℃/min, sintering at 800～1500℃, and finally cooling with furnace.
2. The high-entropy alloy boride ceramic of claim 1, wherein the purity of the Al, Fe, Ni, Co, Cr, and B powders are all 99.95-99.99 wt.%.
3. The high-entropy alloy boride ceramic of claim 1, wherein the particle size of the Al _y (FeNiCoCr) _1-xy B _x powder is 5-45 μm.
4. The preparation method of high-entropy alloy boride ceramics according to any one of claims 1-3, characterized in that it comprises the following specific steps:

   S1. In an argon atmosphere, the Al, Fe, Ni, Co, Cr, B powders are mixed according to the proportions, mixed and evenly placed in a high-energy ball mill for ball milling, and high-entropy alloy boride powder is obtained after ball milling;

   S2. Take out the ball-milled powder, dry and sieving to obtain the high-entropy alloy boride powder that has been solid-solved;

   S3. Put the powder into the spark plasma sintering mold and pre-compress, under the protection of Ar atmosphere, the constant pressure is 10-50Mpa, the temperature is raised to 800-1500℃ at a rate of 50-200℃/min, and the temperature is kept, and finally cooled with the furnace , Prepared high-entropy alloy boride ceramics.
5. The method for preparing high-entropy alloy boride ceramics according to claim 4, characterized in that, in step S1, the rotation speed of the ball mill is 300-1425 rpm, and the ball-to-battery ratio is (2-20):1. The time of ball milling is 5～200h.
6. The method for preparing high-entropy alloy boride ceramics according to claim 4, wherein the particle size of the high-entropy alloy boride powder in step S1 is 5-45 μm.
7. The method for preparing high-entropy alloy boride ceramics according to claim 4, wherein the sintering time in step S3 is 5-30 min.
8. The application of the high-entropy alloy boride ceramics according to any one of claims 1 to 3 in the field of cutting tools.

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