阅读说明：本技术 双尺度颗粒增强金属基构型复合材料、制备方法及应用 (Double-scale particle reinforced metal matrix configuration composite material, preparation method and application ) 是由 蒋业华 祝明明 周谟金 隋育栋 于 2021-09-10 设计创作，主要内容包括：本发明属于金属基复合材料制备技术领域,公开了一种双尺度颗粒增强金属基构型复合材料、制备方法及应用,将纯钛粉和纯碳粉在真空式球磨机中充分搅拌混合后压制成型,并将压制好坯料破碎成颗粒,将颗粒清洗干净去除表面油渍和污染物之后将处理好的颗粒通过网筛,获得颗粒；将所得到的颗粒与不同体积分数的自制诱导剂进行混合,用自制粘结剂搅拌均匀,并填充到蜂窝构型的模具中,烘干、成型,得到含有特定形状的预制体；采用铸渗成型的方法将所得到的预制体与金属液实现浸渗、复合,通过原位反应得到所需的TiC增强金属基复合材料。本发明节约成本,利用浇注过程中发生的自蔓延反应得到颗粒增强金属基复合材料,提高金属与颗粒的结合强度。(The invention belongs to the technical field of metal matrix composite preparation, and discloses a double-size particle reinforced metal matrix configuration composite, a preparation method and application thereof, wherein pure titanium powder and pure carbon powder are fully stirred and mixed in a vacuum ball mill and then are pressed and formed, pressed blanks are crushed into particles, the particles are cleaned, surface oil stains and pollutants are removed, and then the treated particles pass through a mesh screen to obtain particles; mixing the obtained particles with self-made inducers with different volume fractions, uniformly stirring the mixture by using a self-made binder, filling the mixture into a honeycomb-shaped mold, drying and molding the honeycomb-shaped mold to obtain a prefabricated body with a specific shape; and (3) impregnating and compounding the obtained prefabricated body and molten metal by adopting a casting and infiltration forming method, and obtaining the required TiC reinforced metal matrix composite material through in-situ reaction. The invention saves cost, obtains the particle reinforced metal matrix composite material by utilizing the self-propagating reaction generated in the casting process, and improves the bonding strength of metal and particles.)

1. A preparation method of a dual-scale particle reinforced metal matrix composite material is characterized by comprising the following steps:

step one, mixing Ti powder and C powder according to a certain proportion, stirring in a vacuum ball mill, and fully and uniformly mixing to obtain alloy powder mixed by the Ti powder and the C powder;

secondly, placing the alloy powder mixed by the Ti powder and the C powder into a specific die, placing the die on a press machine for pressing, maintaining the pressure, and performing press forming;

step three, crushing the pressed blank by adopting a special experimental method, and sieving for several times by a mesh sieve;

mixing the treated particles with a self-made in-situ inducer with a certain volume fraction, and adding a specific binder for fully stirring to uniformly distribute the original inducer on the surfaces of the ceramic particles;

filling the mixed particles into a honeycomb-shaped mold, drying and molding to prepare a honeycomb-shaped ceramic particle prefabricated body;

step six, the obtained prefabricated body is placed into a cavity for fixing by adopting a casting infiltration method, and casting infiltration is carried out, so that the prefabricated body and the metal solution generate a self-propagating reaction at a high temperature;

and step seven, after the metal liquid is cooled, the TiC particle reinforced steel-based configuration composite material can be obtained.

2. The method for preparing a dual-scale particle reinforced metal matrix composite material according to claim 1, wherein in the first step, the stirring time is 6-36 h.

3. The method for preparing a dual-scale particle reinforced metal matrix composite material according to claim 1, wherein in the second step, the method for press forming comprises the following steps: and (3) placing the die on a press machine, pressing under the pressure of 5-50 Pa, and maintaining the pressure for 3-30 min.

4. The method of preparing a dual-scale particle-reinforced metal-matrix-configured composite material of claim 1, wherein in step three, the mesh number of the mesh screen is 2-6 meshes larger than the minimum mesh number of the reinforcement.

5. The method for preparing a dual-scale particle reinforced metal matrix configuration composite material as claimed in claim 1, wherein in step three, the mesh number of the particles is 8-60 meshes.

6. The method for preparing a dual-scale particle reinforced metal matrix configuration composite material as claimed in claim 1, wherein in the fourth step, the home-made in-situ inducer is a metal powder component comprising one or more of reduced iron powder, high chromium cast iron powder, low chromium cast iron powder, high manganese steel powder, copper powder, silicon powder or alloy powder.

7. The method for preparing a dual-scale particle reinforced metal matrix configuration composite material according to claim 1, wherein in the fourth step, the binder is one or more of water glass, silica sol, polyvinyl alcohol or cellulose.

8. The method for preparing the dual-scale particle reinforced metal matrix configuration composite material as claimed in claim 1, wherein in the fourth step, the added inducer and the binder respectively account for 1% -90% and 1% -30% of the mass of the reinforcement particles by mass percentage with reference to the mass of the reinforcement particles;

in the seventh step, the size of TiC particles generated by the in-situ reaction of the reinforcing particles containing different volume fractions of the inducer after infiltration is different, and the TiC particles generated by the reinforcing particles of each volume fraction of the inducer after infiltration macroscopically form millimeter-sized particles, but microscopically the particles are in micron-sized sizes.

9. The dual-scale particle reinforced metal matrix composite material prepared by the method for preparing the dual-scale particle reinforced metal matrix composite material as claimed in any one of claims 1 to 8.

10. Use of the dual-scale particle reinforced metal matrix composite of claim 9 for wear resistance of steel.

Technical Field

The invention belongs to the technical field of metal matrix composite preparation, and particularly relates to a double-scale particle reinforced metal matrix composite, a preparation method and application.

Background

At present, the traditional steel wear-resistant materials mainly comprise high-chromium cast iron, high-manganese steel, alloy steel and the like, and the traditional wear-resistant materials are mainly applied to industries such as metallurgy, electric power, coal, engineering machinery and the like. Such as crushers and excavators, ball mills, metal mills, etc. in the metallurgical industry; coal mills used in the power industry, and vertical mill grinding rolls, liners and the like used in the cement industry. The traditional wear-resistant materials are increasingly difficult to meet the severe requirements of complex working conditions due to the limitations of the traditional wear-resistant materials. At present, the particle reinforced metal matrix composite material has the advantages of high toughness of a metal matrix and high strength and high hardness of special particles, and the two materials are combined with each other to greatly reduce the wear loss of the material, and simultaneously can exert the advantages of the high toughness of the metal, so that the wear of the material can be reduced to a great extent, the service life of a wear-resistant part is prolonged, the consumption of the material is reduced, the cost is greatly saved, and the particle reinforced metal matrix composite material is more and more favored by people. Among numerous particles, carbide granular carbon has the characteristics of high hardness, high melting point, high modulus, small thermal expansion coefficient with metal and the like, and becomes one of the optimal special reinforcements of the composite material. Among numerous carbides, titanium carbide has low density, small thermal expansion coefficient, high strength, high wear resistance, corrosion resistance and oxidation resistance, and is one of the hottest iron and steel based composite material reinforcements. But because the market price of the titanium carbide is expensive, the production cost is greatly increased, which is contrary to the low-cost development concept. Therefore, a new preparation method is selected to produce the TiC reinforced steel-based composite material, so that the composite material can meet the requirements and save the cost, and the research hotspot is formed.

Through the above analysis, the problems and defects of the prior art are as follows: the traditional wear-resistant materials are increasingly difficult to meet the severe requirements of complex working conditions due to the limitations of the traditional wear-resistant materials. Meanwhile, the market price of the titanium carbide is expensive, so that the production cost is greatly increased, which is contrary to the low-cost development concept.

The difficulty in solving the above problems and defects is: the problem that the wettability of the reinforced particles and a metal matrix is poor in the particle reinforced metal matrix composite material generally exists, and the additional ceramic particles which are good in wettability with the metal matrix and high in hardness are difficult to find.

The significance of solving the problems and the defects is as follows: by preparing the dual-scale TiC particle reinforced steel-based composite material, the waste phenomenon of material resources can be greatly reduced, the reinforced particles obtained by the in-situ generation method have good wettability with a metal matrix, the interface is clean and pollution-free, the bonding capability of the interface is improved, and meanwhile, the preparation process and time can be shortened. Provides theoretical support for further development of the particle reinforced metal matrix composite material and has a certain positive effect on reducing energy consumption.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a double-scale particle reinforced metal matrix configuration composite material, a preparation method and application.

The invention is realized in such a way that a preparation method of a dual-scale particle reinforced metal matrix composite material comprises the following steps:

step one, mixing Ti powder and C powder according to a certain proportion, stirring in a vacuum ball mill, and fully and uniformly mixing to obtain alloy powder mixed by the Ti powder and the C powder; the mixed metal powder obtained by mixing by adopting the vacuum ball mill is more uniform than that obtained by manually mixing, and the oxidation of the metal powder can be avoided in a vacuum environment;

secondly, placing the alloy powder mixed by the Ti powder and the C powder into a specific mould, placing the mould on a press machine for pressing, maintaining pressure, and performing press forming to obtain a preform with certain strength, so that later-stage experiment operation is facilitated;

step three, crushing the pressed blank by adopting a special experimental method, and sieving for several times by a mesh sieve to ensure that the obtained particles are basically consistent in size; ceramic particles with a certain size are made into a prefabricated body, so that the metal liquid can be infiltrated conveniently, and the ceramic particles with uniform particle size can be obtained as much as possible, so that the accuracy of experimental data can be ensured;

mixing the treated particles with a self-made in-situ inducer with a certain volume fraction, adding a specific binder, and fully stirring to uniformly distribute the original inducer on the surfaces of the ceramic particles, wherein the addition of the inducer can avoid the agglomeration of TiC particles generated in the in-situ reaction process, so that the reinforcing particles and the TiC particles which are dispersedly distributed in the metal matrix are ensured to the maximum extent, and the TiC particles obtained after the in-situ reaction of the particles containing different inducers are different in size;

filling the mixed particles into a honeycomb-shaped mold, drying and molding to prepare a honeycomb-shaped ceramic particle preform, wherein the honeycomb configuration not only enables the preform to have certain strength, but also facilitates infiltration of molten metal;

and sixthly, placing the obtained prefabricated body into a cavity for fixing by adopting a casting infiltration method, and performing casting infiltration to enable the prefabricated body and the metal solution to perform self-propagating reaction at high temperature so as to obtain the expected TiC particle reinforced metal matrix composite material.

And step seven, after the metal liquid is cooled, the TiC particle reinforced steel-based configuration composite material can be obtained.

Further, in the first step, the stirring time is 6-36 hours, and the uniformity of the mixed metal powder can be good in the time period;

further, in the second step, the method for press forming comprises: placing the die on a press machine, pressing under the pressure of 5-50 Pa, and maintaining the pressure for 3-30 min to obtain a pressed blank with ideal strength;

further, in the third step, the mesh number of the mesh screen is 2-6 mesh numbers larger than the minimum mesh number of the reinforcement body, so that particles with uniform size can be obtained;

furthermore, in the third step, the mesh number of the particles is 8-60 meshes, and the obtained reinforced particles with the mesh number can ensure impregnation to the maximum extent and show good wear resistance;

further, in the fourth step, the self-made in-situ inducer is a metal powder component, and comprises one or more of reduced iron powder, high-chromium cast iron powder, low-chromium cast iron powder, high-manganese steel powder, copper powder, silicon powder or alloy powder, the addition of the inducer can avoid the agglomeration phenomenon of TiC particles generated in the in-situ reaction process, the reinforcing particles and the TiC particles are ensured to be distributed in the metal matrix in a dispersed manner to the maximum extent, and the TiC particles obtained after the in-situ reaction of the particles containing different inducers are different in size;

further, in the fourth step, the binder is one or more of water glass, silica sol, polyvinyl alcohol or cellulose, and the binder is used for making the particles into a prefabricated body with a honeycomb structure;

furthermore, in the fourth step, the added inducer and the binder respectively account for 1-90% and 1-30% of the mass fraction by taking the mass of the particles of the reinforcement as a reference, the dispersion degree of the particles with too little inducer is insufficient, and the strength of the prefabricated body obtained by adding too little binder is not high.

Furthermore, in the seventh step, the sizes of TiC particles generated by in-situ reaction of the reinforcing particles containing different volume fractions of the inducing agents after casting infiltration are different, and the TiC particles generated by the reinforcing particles of each volume fraction of the inducing agents after casting infiltration macroscopically form millimeter-sized particles, but microscopically the particles are micron-sized particles, the sizes of the TiC particles obtained by different contents of the inducing agents are different, and the double-sized particles are mixed and enhanced, so that the wear resistance and the service life of the parts are further improved.

The invention also aims to provide the dual-scale particle reinforced metal matrix composite prepared by the preparation method. The metal matrix is high manganese steel, high chromium cast iron or alloy steel.

The invention also aims to provide application of the dual-scale particle reinforced metal matrix configuration composite material in wear resistance of steel.

By combining all the technical schemes, the invention has the advantages and positive effects that: the invention provides a preparation method of a double-scale particle reinforced metal matrix configuration composite material, which comprises the steps of fully stirring and mixing pure titanium powder and pure carbon powder in a vacuum ball mill according to a certain proportion, then carrying out compression molding under a certain pressure, crushing a pressed blank into particles with the size of 8-60 meshes by adopting a special treatment mode, cleaning the particles, removing oil stains and pollutants on the surface, and then passing the treated particles through a mesh screen with a certain mesh number to obtain particles with the same size. Fully mixing the obtained particles with self-made inducers with different volume fractions, uniformly stirring the mixture by using a self-made binder, filling the mixture into a honeycomb-shaped mold, drying and molding the honeycomb-shaped mold to obtain a prefabricated body with a specific shape; and finally, impregnating and compounding the obtained prefabricated body and molten metal by adopting a casting and infiltration forming method, and obtaining the required TiC reinforced metal matrix composite material through in-situ reaction. The surface of TiC particles is pollution-free and well combined with a matrix. Because of the different volume fractions of the inducer in the added reinforcement particles, the sizes of the obtained TiC reinforcement particles generated in situ are different, the TiC particles in the composite material obtained after casting and infiltration containing the inducer with different volume fractions are millimeter-sized particles macroscopically and micron-sized fine particles microscopically, and the TiC particles are arranged macroscopically according to a honeycomb configuration, so the composite material is called as a dual-scale TiC particle reinforced steel-iron-based configuration composite material.

The method takes Ti powder and C powder as starting points, utilizes a traditional casting infiltration experimental method to press and form the mixed Ti powder and C powder and crush the powder into particles, mixes the particles with original inducers with different volume fractions, and utilizes a binding agent to prepare the honeycomb-shaped preform, so that the honeycomb-shaped preform and high-temperature metal liquid are subjected to high-temperature self-propagating synthesis in the casting process, thereby obtaining the TiC particle reinforced metal-based composite material, and the TiC particles are millimeter-sized particles and have a honeycomb configuration in a macroscopic view and micron-sized particles in a microscopic view.

According to the invention, Ti powder and C powder which are mixed according to a certain proportion are selected for compression molding, and then are crushed by a specific method to prepare the honeycomb-shaped preform, so that the cost is effectively saved, and the composite area interface can be controlled. According to the invention, the Ti powder and the C powder are mixed, so that the experiment cost can be greatly reduced, the high cost for directly purchasing TiC is saved, the content ratio of the Ti powder and the C powder can be freely controlled, and convenience is provided for optimizing subsequent performance. The surface of TiC particles is pollution-free and well combined with a matrix.

The TiC column top or the particles thereof sold directly on the market are not adopted, but Ti powder and C powder are mixed and then are pressed and molded, then are crushed by a specific method, and are mixed with a self-made original as an inducer and a binder to prepare a prefabricated body for pouring, and the prefabricated body is further prepared by the method, so that the cost can be saved, the self-propagating reaction generated in the pouring process can be utilized to obtain the particle reinforced metal matrix composite material, and the bonding strength of metal and the particles is improved to a certain extent; the method is characterized in that a self-made original is added to the surface of the particles as an inducer, a reactive interface is provided in the casting process, TiC particles with different sizes are obtained according to the difference of volume fractions of the added in-situ inducer, and the control of the particle size and the distribution is realized by adjusting the content of the in-situ inducer.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments of the present invention will be briefly described below, and it is obvious that the drawings described below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a flow chart of a method for preparing a dual-scale particle-reinforced metal matrix composite material according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of a composite material provided by an embodiment of the present invention.

FIG. 3 is a schematic metallographic microstructure of a composite material according to an embodiment of the present invention.

Fig. 4 is a local area scanning electron microscope image of the TiC particle reinforced steel-based composite material provided in the embodiment of the present invention.

Fig. 5 is a schematic view of a liner provided in an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Aiming at the problems in the prior art, the invention provides a dual-scale particle reinforced metal matrix configuration composite material, a preparation method and application thereof, and the invention is described in detail below with reference to the accompanying drawings.

As shown in fig. 1, the preparation method of the dual-scale particle-reinforced metal matrix composite material provided by the embodiment of the invention comprises the following steps:

s101, mixing Ti powder and C powder according to a certain proportion, stirring in a vacuum ball mill, and fully and uniformly mixing to obtain alloy powder mixed by the Ti powder and the C powder;

s102, placing the alloy powder mixed by the Ti powder and the C powder into a specific die, placing the die on a press machine for pressing, maintaining the pressure, and performing compression molding;

s103, crushing the pressed blank by adopting a special experimental method, and sieving for several times by using a mesh sieve to ensure that the obtained particles are basically consistent in size;

s104, mixing the treated particles with a self-made in-situ inducer with a certain volume fraction, and adding a specific binder for fully stirring to uniformly distribute the original inducer on the surfaces of the ceramic particles;

s105, filling the mixed particles into a honeycomb-shaped mold, drying and molding to prepare a honeycomb-shaped ceramic particle preform;

s106, placing the obtained prefabricated body into a cavity for fixing by adopting a casting infiltration method, and performing casting infiltration to enable the prefabricated body and the metal solution to generate a self-propagating reaction at a high temperature;

and S107, after the molten metal is cooled, obtaining the TiC particle reinforced steel-based configuration composite material.

The technical solution of the present invention will be further described with reference to the following examples.

Example 1

The impact and cutting of the impact breaking hammer are carried out to the maximum extent in the fine crushing process, so that the impact breaking hammer has higher requirements on the hardness and the wear resistance; the larger the impact breaking hammer type number is, the heavier the weight of the plate hammer is, the larger the granularity of the broken material is, and the higher the unit yield is; meanwhile, the larger the impact on the impact breaking hammer is, the hardness of the plate hammer is improved to the maximum extent on the premise of ensuring the toughness of the plate hammer when the impact breaking hammer is selected. The simple dual-scale TiC particle reinforced high-chromium cast iron-based plate hammer is manufactured at present, and the working conditions of the plate hammer are simulated, wherein the method comprises the following specific steps:

(1) 1mol of Ti powder and 1mol of C powder are prepared according to the proportion, and then stirred in a ball mill for 12 hours to be fully and uniformly mixed, so that alloy powder mixed with the required Ti powder and C powder is obtained;

(2) putting the mixed powder on a press, and carrying out press forming under the pressure of 20Pa and the pressure maintaining for 20 minutes;

(3) placing the pressed blank in a shattering machine for shattering, and sieving for several times through a mesh sieve to obtain particles with the size basically consistent with that of the obtained particles and the mesh number of 16;

(4) weighing 100g of the processed particles, mixing the particles with 6g of the self-made original inducer together, adding 10g of the binder, fully stirring, calling the mixed particles as particles A, weighing 100g of the particles again, mixing the particles with 20g of the self-made original inducer together, adding 10g of the binder, fully stirring, calling the mixed particles as particles B, uniformly mixing the particles A and the particles B, filling the mixed particles into a honeycomb-shaped mold, drying, forming and preparing into a prefabricated body.

(5) And (3) placing the obtained prefabricated body into a cavity for fixing, and performing casting infiltration to enable the prefabricated body and the metal solution to perform self-propagating reaction at high temperature.

(6) And after the metal liquid is cooled, sampling to obtain the required TiC particle reinforced steel-based composite material with double-scale configuration. A schematic of the composite material is shown in fig. 2. Meanwhile, TiC particles obtained after casting and infiltration of the particles A and the particles B are millimeter-sized particles in a macroscopic view and are micron-sized particles in a microscopic view.

(7) By using laboratory conditions, the comparison of the pure high-chromium cast iron matrix plate hammer and the prepared double-scale TiC particle reinforced high-chromium cast iron plate hammer shows that the working time of the prepared composite plate hammer is doubled compared with that of the pure matrix plate hammer.

Example 2

The end of the hammer head of the hammer crusher, which is impacted with the material, mainly bears the impact force and the friction force and needs sufficient hardness and wear resistance, while the hammer handle mainly bears the alternating bending stress and has certain strength and revival. For a single material, the two are mutually contradictory, and the plasticity is reduced by increasing the hardness and the wear resistance. The mass of the hammer head is in direct proportion to the crushing capacity, but the energy consumption is increased by increasing the mass, and the cost is increased; the simple dual-scale TiC particle reinforced alloy steel-based hammer is manufactured at present, the working condition of the hammer is simulated, and the specific steps are as follows:

(1) 1mol of Ti powder and 0.8mol of C powder are prepared according to the proportion and stirred in a ball mill for 15 hours to be fully and uniformly mixed, so that alloy powder mixed with the required Ti powder and the C powder is obtained;

(2) putting the mixed powder on a press, and carrying out press forming under the pressure of 30Pa and the pressure maintaining for 15 minutes;

(3) crushing the pressed tablets, and sieving for several times by a mesh sieve to obtain particles with the size basically consistent with that of the obtained particles, so as to obtain particles with the mesh number of 20;

(4) weighing 100g of the treated particles, mixing the particles with 30g of the self-made in-situ inducer, adding 30g of the binder, and fully stirring to uniformly distribute the metal powder on the surfaces of the ceramic particles; and filling the mixed particles into a common mould without a configuration, drying and forming to prepare a prefabricated body.

(5) The obtained prefabricated body is placed in a cavity for fixing by adopting a casting infiltration method, casting infiltration is carried out, alloy steel is selected as a metal matrix, and the prefabricated body and molten metal are subjected to self-propagating reaction at high temperature in the casting process. Thus obtaining the TiC particle reinforced alloy steel-based composite material.

(6) And after the metal liquid is cooled, obtaining the required double-scale TiC particle reinforced steel-based composite material. As shown in fig. 3, which is a schematic metallographic microstructure of the composite material, it can be seen from fig. 3 that the reinforcement particles are represented macroscopically as millimeter-sized particles and microscopically as micron-sized particles. As shown in FIG. 4, it can be seen from the scanning electron microscope image of the composite material that TiC generated in situ is relatively uniformly distributed in the metal matrix, and the average particle size is 1-2 um.

(7) The comparison of the pure alloy steel matrix hammerhead and the prepared double-scale TiC particle reinforced alloy steel matrix hammerhead shows that the mass loss of the prepared composite alloy steel hammerhead is reduced by 1.5 times compared with the mass loss of the hammerhead of the pure alloy steel matrix by using laboratory conditions.

Example 3

Wear of wear liners is generally of two types, high stress wear and gouging wear. For high stress abrasion, the surface of the lining plate is required to have the highest hardness to resist the pressure of the grinding material, and the wear-resisting plate reduces the phenomenon of surface embrittlement and shedding. For gouging wear, the wear resistant liner is required to be able to withstand certain impact loads: the ball mill lining plate, the iron forging and the lining brick for the vertical kiln are mainly subjected to high-stress abrasion due to the fact that the impact force generated by the grinding materials is not large. The method comprises the following steps of preparing a simple double-scale TiC particle reinforced high manganese steel base lining plate, and simulating the working conditions of the lining plate:

(1) 1mol of Ti powder and 0.5mol of C powder are prepared according to the proportion and stirred in a ball mill for 24 hours to be fully and uniformly mixed, so that alloy powder mixed with the required Ti powder and the C powder is obtained;

(2) putting the mixed powder on a press, and carrying out press forming under the pressure of 20Pa and the pressure maintaining for 20 minutes;

(3) crushing the pressed tablets, and sieving for several times by a mesh sieve to obtain particles with the size basically consistent with that of the obtained particles, so as to obtain particles with the mesh number of 60 meshes;

(4) weighing 100g of the treated particles, mixing the particles with 5g of high-chromium cast iron, and adding 8g of binder for fully stirring to uniformly distribute metal powder on the surfaces of the ceramic particles; and filling the mixed particles into a honeycomb-shaped mold, drying and molding to prepare a prefabricated body.

(5) And (3) placing the obtained prefabricated body into a cavity for fixing by adopting a cast-infiltration method, and carrying out cast-infiltration to ensure that the prefabricated body and the metal solution generate a self-propagating reaction at a high temperature.

(6) And after the metal liquid is cooled, obtaining the required double-scale TiC particle reinforced steel-based configuration composite material. The macroscopic shape of the composite material is a lining plate, so that the composite material can be applied to the specific working condition to give full play to the characteristic of good wear resistance, thereby reducing the loss of the material and realizing the mass production of the composite material. A schematic of the composite is shown in fig. 5. Wherein the TiC particles in the honeycomb configuration are all millimeter-sized particles on a macroscopic scale, and show micron-sized particles on a microscopic scale.

(7) By utilizing laboratory conditions, comparing the pure high manganese steel substrate lining plate with the prepared double-scale TiC particle reinforced high manganese steel lining plate, the comparison shows that the furrow depth of the prepared pure high manganese steel lining plate is 1.6 times deeper than that of the pure composite high manganese steel lining plate.

The above description is only for the purpose of illustrating the present invention and the appended claims are not to be construed as limiting the scope of the invention, which is intended to cover all modifications, equivalents and improvements that are within the spirit and scope of the invention as defined by the appended claims.