CN114409410A - Method for manufacturing pressureless sintering silicon carbide ceramic grinding disc - Google Patents

Method for manufacturing pressureless sintering silicon carbide ceramic grinding disc Download PDF

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CN114409410A
CN114409410A CN202210133138.3A CN202210133138A CN114409410A CN 114409410 A CN114409410 A CN 114409410A CN 202210133138 A CN202210133138 A CN 202210133138A CN 114409410 A CN114409410 A CN 114409410A
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powder
silicon carbide
carbon fiber
fiber woven
woven body
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CN114409410B (en
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陈志伟
李乐乐
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Henan Yalian New Material Co ltd
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Henan Yalian New Material Co ltd
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
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Abstract

The invention discloses a method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc, which comprises the following specific steps: preparing granulation powder, adding a toughening material, dipping a carbon fiber woven body, preforming a grinding disc blank, processing the grinding disc blank, sintering the grinding disc blank, and processing the grinding disc. The grinding disc prepared by the method has good toughness, high radial strength and good reliability; the method has the advantages of simple process, low production cost and high production efficiency, and is suitable for industrially preparing the high-performance silicon carbide ceramic grinding disc.

Description

Method for manufacturing pressureless sintering silicon carbide ceramic grinding disc
Technical Field
The invention relates to the technical field of silicon carbide ceramic grinding materials, in particular to a method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc.
Background
The grinding process is a common process for finishing a processing surface by utilizing the relative motion of a grinding tool (a grinding disc/sheet) and a workpiece under a certain pressure, and the grinding process also needs to select abrasive particles with proper types and particle sizes to improve the processing efficiency and ensure the processing quality. The grinding process can be used for processing various metal and non-metal materials, and has wide application in the fields of precious stones, ceramics, mobile phones, wafers and the like.
The grinding disc is an important key component of grinding processing equipment. When grinding, the grinding disc rotates to drive the abrasive particles to flexibly grind or polish the workpiece, and the abrasive particles can grind the workpiece and also can grind the grinding disc, namely, the grinding disc is worn and consumed. Therefore, the material and performance of the grinding disc have great influence on the grinding efficiency and quality. In addition to a high geometric accuracy of the working surface, the grinding disk should satisfy the following requirements: 1) the structure is reasonable, and the rigidity, the precision retentivity and the wear resistance are good; 2) the material has proper hardness, and the uniformity and the consistency of the hardness in the surface are good; 3) the grinding disc has uniform and compact tissue and no defects of impurities, foreign matters, air holes, cracks and the like; 4) the machined surface is provided with proper groove arrangement, so that the chip removal and containing performance is good, and the heat dissipation performance is good.
The materials of the prior commonly used grinding disc mainly comprise copper, tin, stainless steel, cast iron, resin and the like, and the application occasions of the grinding discs made of different materials are different. The copper disc is mainly used for fine grinding of workpieces such as sapphire and the like; tin plates are also used mainly for refining, such as for example of ceramic products; stainless steel discs are commonly used for the fine grinding of metal products; the iron plate is mainly used for rough grinding, such as rough grinding of iron and alloy steel products.
Chips have an important key position in the modern high-tech field, and wafers manufactured by cutting, grinding and polishing crystal ingots are the basis for preparing the chips. For example, in the semiconductor industry, a polishing disk made of cast iron or carbon steel is commonly used, but the cast iron or carbon steel has relatively low hardness and rigidity, poor oxidation resistance and corrosion resistance, and poor wear resistance, and thus has a short service life. And the coefficient of thermal expansion is large, the thermal conductivity is low, and the flatness and parallelism of the silicon wafer are difficult to ensure due to abrasion and thermal deformation of the grinding disc during the process of processing the silicon wafer, particularly during high-speed grinding or polishing. With the increasing popularity of the third generation semiconductor silicon carbide single crystal, it has been difficult for conventional metal abrasive disks to meet their requirements for high speed grinding or polishing due to the higher hardness of the silicon carbide single crystal.
The silicon carbide ceramic has the advantages of high hardness, wear resistance, corrosion resistance, high rigidity, high thermal conductivity, small thermal expansion coefficient, good chemical stability and the like, so that the silicon carbide ceramic becomes an ideal material for high-speed precision grinding and polishing grinding discs of wafers, sapphire panels, solar silicon wafers, electronic ceramics and the like. However, silicon carbide ceramics have poor toughness, and when they are used as polishing disks for high-speed polishing, the centrifugal force exceeds the tensile strength thereof, which may cause damage to the polishing disks.
Therefore, the problem to be solved is to improve the toughness of the silicon carbide ceramic grinding disc.
Disclosure of Invention
In view of the above, the present invention provides a method for manufacturing a pressureless sintered silicon carbide ceramic grinding disk with high toughness, which solves the problems of poor reliability and easy radial cracking of the grinding disk caused by poor toughness of silicon carbide ceramic.
In order to achieve the purpose, the invention adopts the following technical scheme:
a pressureless sintering silicon carbide ceramic grinding disc manufacturing method, raw materials for preparing the grinding disc comprise a matrix material and a toughening material; the matrix material comprises, by mass, 100 parts of silicon carbide micro powder, 0.5-3 parts of boron carbide micro powder, 5-15 parts of adhesive, 0.5-3 parts of surfactant and 0.5-2 parts of dispersant; the toughening material is carbon fiber and a carbon fiber woven body, and the addition amount of the carbon fiber is 0-15% of the total amount of the matrix material;
the manufacturing method specifically comprises the following steps:
(1) preparation of granulated powder
Weighing the matrix material according to the proportion, adding deionized water, wherein the using amount of the deionized water is 0.9-1.5 times of the mass of the silicon carbide micro powder, and then performing ball milling for 8-20 hours to prepare silicon carbide ceramic slurry; then, carrying out spray granulation on the silicon carbide ceramic slurry to obtain granulated powder; the water content of the granulated powder is 0.5-1.2%, and the mass ratio of the granulated powder with the granularity of 60-180 meshes is more than 95%;
(2) adding toughening material
Adding short carbon fibers into the granulated powder, and mixing by using a vibrating screen;
(3) impregnation treatment of carbon fiber woven body
Weaving carbon fibers into a carbon fiber woven body with a two-dimensional mesh structure, wherein the length and the width of meshes of the carbon fiber woven body are respectively 3-50mm and 3-50 mm; then dipping the carbon fiber bundles in the mixed slurry to ensure that the surface of the carbon fiber bundles is fully distributed with the mixed slurry, wherein the mixed slurry is prepared by mixing nano carbon powder, nano silicon powder, a binder, a dispersing agent and deionized water by wet ball milling for 8-20 hours;
then placing the carbon fiber woven body in a vacuum drying oven, placing the carbon fiber woven body for 5-20h at the temperature of 25-35 ℃, and then heating to 60-80 ℃ for drying for 10-30h to dry the carbon fiber woven body; soaking the dried carbon fiber woven body in the mixed slurry again, and repeating the steps for multiple times to ensure that the surface of the dried carbon fiber woven body is uniformly coated with a layer of silicon powder and carbon powder;
dipping the carbon fiber woven body, thereby improving the interface bonding strength of the carbon fiber and the silicon carbide ceramic matrix; the radial strength of the silicon carbide ceramic can be obviously improved by the mesh design of the carbon fibers, and because the meshes are too small, granulated powder is not easy to enter a woven body, so that the silicon carbide ceramic matrix is easy to layer; the mesh size is too large, and the toughening effect is not obvious;
(4) preforming of abrasive disk blanks
Laying a layer of silicon carbide granulation powder added with short carbon fibers in a mould, compacting and flattening the silicon carbide granulation powder on a vibration platform, laying a soaked carbon fiber woven body, laying a layer of silicon carbide granulation powder added with short carbon fibers, and vertically tamping the carbon fiber woven body by using a blunt metal rod, wherein the tip diameter of the metal rod is smaller than the mesh size of the carbon fiber woven body; part of the short carbon fibers are distributed in the vertical direction by up and down pounding, so that the toughness of the silicon carbide ceramic is improved, and the powder laying density is improved; the laying thickness of the granulation powder and the carbon fiber braided body can be adjusted according to the thickness of the grinding disc;
performing compression molding on the mold after the vibration and flattening to obtain a preformed blank of the grinding disc, and performing cold isostatic pressing on the preformed blank after packaging and vacuumizing, wherein the pressure of the cold isostatic pressing is 120-250MPa, and the pressure maintaining time is 5-30 min;
(5) machining of abrasive disk blanks
Drying the grinding disc blank formed by cold isostatic pressing at 80-150 ℃ for 8-20 hours; then turning to obtain a flat surface and required appearance and size, and machining a groove with required shape and size on the working surface according to the requirement;
(6) sintering of abrasive disk blanks
Placing the processed grinding disc blank in a vacuum sintering furnace, heating to 1450-;
(7) manufacture of abrasive discs
And grinding, lapping and polishing the sintered body of the lapping disc to obtain the silicon carbide ceramic lapping disc with required specification, shape, size and flatness.
Preferably, the carbon fiber woven body and the chopped carbon fibers are high-strength carbon fibers, and the tensile strength of the high-strength carbon fibers is not less than 2500 MPa; wherein the length of the chopped carbon fiber is 3-5mm, and the diameter of the tow is less than 100 mu m; the diameter of the carbon fiber braided body tows is less than 200 mu m.
Preferably, D of the fine silicon carbide powder500.45. + -. 0.2. mu.m.
Preferably, D of the boron carbide fine powder50Is 1.50 +/-1 mu m.
Preferably, the surfactant is stearic acid or fatty glyceride; the dispersant is tetramethyl ammonium hydroxide or polyacrylic acid.
Preferably, the binder is a phenolic resin, polyvinyl alcohol or carboxymethyl cellulose.
Preferably, the molar ratio of the nano carbon powder to the nano silicon powder in the step (3) is 1: 1.05-1.25 percent, the addition amount of the binder is 2-10 percent of the total mass of the nano carbon powder and the nano silicon powder, the addition amount of the dispersant is 0.5-3 percent of the total mass of the nano carbon powder and the nano silicon powder, and the ratio of the deionized water to the total mass of the nano carbon powder and the nano silicon powder is 1.0-2.0: 1; wherein D of the nano carbon powder and the nano silicon powder50Are not more than 100 nm. Preferably, the dispersant in step (3) is polyvinylpyrrolidone or tetramethylammonium hydroxide.
Preferably, the binder in step (3) is polyvinyl alcohol or carboxymethyl cellulose.
The invention has the beneficial effects that:
according to the invention, the silicon carbide ceramic is toughened through the high-strength two-dimensional carbon fiber braided body, so that the toughness and reliability of the silicon carbide ceramic grinding disc are improved; the nano silicon powder and the nano carbon powder coated on the carbon fiber braided body tows are subjected to in-situ reaction by an impregnation method to generate the silicon carbide, so that the interface bonding strength of the carbon fibers and the silicon carbide ceramic matrix is improved, and the toughening effect of the grinding disc is enhanced.
By adding the short carbon fibers and adopting a vertical up-down tamping mode, the short carbon fibers are vertical to the two-dimensional carbon fiber woven body, and the toughening effect in the vertical direction is achieved.
The vibrating platform is adopted to stamp and pave to become technology to combine mould pressing pre-compaction shaping, cold isostatic pressing shaping technology preparation abrasive disc unburned bricks, can improve unburned bricks homogeneity, improve unburned bricks density, intensity, the unburned bricks processing of being convenient for, and guarantee the homogeneity, the uniformity of final product.
The invention adopts a fine-bundle two-dimensional carbon fiber braided body and combines the short carbon fibers which are vertically distributed, and simultaneously enhances the strength and the toughness of the silicon carbide ceramic in the horizontal and vertical directions. The problem that the pressureless silicon carbide blank containing the three-dimensional carbon fiber braided body is difficult to shrink and densify due to the fact that the pressureless sintered silicon carbide ceramic can shrink in volume is solved, and particularly the problems that the thick-bundle three-dimensional carbon fiber braided body is easy to shrink and low in density are solved.
Compared with the method for preparing the carbon fiber reinforced and toughened silicon carbide ceramic material by adopting the three-dimensional carbon fiber woven body as the matrix skeleton and utilizing the melting infiltration process and the chemical vapor infiltration process, the method has the advantages of simple process, low production cost and high production efficiency, and is suitable for industrially preparing the high-performance silicon carbide ceramic grinding disc.
Detailed Description
The invention is further described below using examples.
Example 1
A method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc comprises the following steps:
(1) preparation of granulated powder
Weighing the matrix materials according to the proportion: 100 parts of silicon carbide micro powder, 0.5 part of boron carbide micro powder, 5 parts of phenolic resin, 0.5 part of stearic acid and 0.5 part of tetramethyl ammonium hydroxide.
And then adding the weighed matrix material into 90 parts of deionized water, and carrying out ball milling in a roller ball mill for 8 hours to obtain the silicon carbide ceramic slurry.
Spraying and granulating the silicon carbide ceramic slurry by using a centrifugal spray tower to obtain granulated powder; the moisture content of the granulated powder was measured to be 0.7%, and the mass ratio of the granulated powder having a particle size of 60-180 mesh was 96.5%.
(2) Adding toughening material
Weighing 100 parts of granulation powder, adding 2 parts of chopped carbon fibers with the length of 3mm and the tow diameter of 50 mu m, and uniformly mixing by using a vibrating screen.
(3) Impregnation treatment of carbon fiber woven body
100 parts of nano carbon powder, 250 parts of nano silicon powder, 18 parts of polyvinyl alcohol and 3.5 parts of polyvinylpyrrolidone, adding 450 parts of deionized water, and ball-milling for 14 hours in a roller ball mill to prepare the mixture slurry of the nano silicon powder and the nano carbon powder.
Placing a two-dimensional mesh-shaped carbon fiber woven body with a tow diameter of 80 mu m and a mesh length and a mesh width of 10mm and 10mm respectively in mixed slurry for soaking for 5min, wherein the carbon fiber woven body can shake in the slurry in the soaking process, so that the surface of the carbon fiber woven body is fully covered with nano silicon powder and nano carbon powder.
Then placing the carbon fiber woven body in a vacuum drying oven, placing the carbon fiber woven body for 20 hours at 25 ℃, and then heating to 60 ℃ to dry the carbon fiber woven body for 30 hours to dry the carbon fiber woven body; and then, putting the dried carbon fiber woven body into the mixed slurry again for dipping, and repeating the steps of dipping and drying for 3 times to uniformly coat a layer of nano silicon powder and nano carbon powder on the surface of the dried carbon fiber woven body.
(4) Preforming of abrasive disk blanks
Firstly paving a layer of silicon carbide granulation powder containing short carbon fibers with the thickness of 40mm in a stainless steel mould with the inner diameter of 600mm on a vibration platform, then paving a soaked carbon fiber woven body, vertically tamping up and down in a mesh of the carbon fiber woven body by using a blunt metal rod with the tip diameter of 5mm, vibrating and flattening, paving a layer of silicon carbide granulation powder added with the short carbon fibers with the thickness of 20mm, paving a soaked carbon fiber woven body, vertically tamping up and down in the mesh of the woven body by using a blunt metal rod with the tip diameter of 5mm, vibrating and flattening; laying a layer of silicon carbide granulation powder with the thickness of 20mm and added with short carbon fibers, laying the impregnated carbon fiber braided body, vertically tamping the carbon fiber braided body up and down in the mesh of the braided body by using a blunt metal rod with the tip diameter of 5mm, and vibrating and compacting and flattening; then, a layer of silicon carbide granulation powder mixed with the short carbon fibers and having a thickness of 40mm is paved, a blunt metal rod with a tip diameter of 5mm is used for vertically tamping up and down in meshes of the woven body, and the woven body is vibrated to compact and flatten.
And performing compression molding on the mold after the vibration compaction and the flattening to obtain a preformed blank of the grinding disc, and performing cold isostatic pressing on the preformed blank after packaging and vacuumizing, wherein the pressure of the cold isostatic pressing is 120MPa, and the pressure maintaining time is 30 min.
(5) Machining of abrasive disk blanks
Drying the grinding disc blank formed by cold isostatic pressing at 80 ℃ for 20 hours; and then turning to obtain a cylinder with an outer diameter of 580mm, a thickness of 70mm and two planar upper and lower surfaces. A plurality of rows of concentric circular grooves are machined in one plane of the cylinder, the depth of each groove is 3mm, the width of each groove is 1.5mm, and the distance between the grooves is 10 mm.
(6) Sintering of abrasive disk blanks
And placing the processed grinding disc blank in a vacuum sintering furnace, heating to 1450 ℃, preserving the temperature for 5 hours, enabling the nano silicon powder and the nano carbon powder coated on the carbon fiber woven body to react in situ to generate silicon carbide, improving the interface bonding strength of the carbon fiber and the silicon carbide ceramic matrix, and then sintering at 2100 ℃ for 7 hours to obtain the grinding disc sintered body.
(7) Manufacture of abrasive discs
And grinding, lapping and polishing the sintered body of the lapping disc to obtain the silicon carbide ceramic lapping disc with required specification, shape, size and flatness.
Through detection, the obtained silicon carbide ceramic grinding disc has the relative density of 98.5 percent, the Vickers microhardness of 24.5GPa, the three-point bending strength of 610.7MPa and the fracture toughness of 8.4 MPa.m1/2
Example 2
A method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc comprises the following steps:
(1) preparation of granulated powder
Weighing the matrix materials according to the proportion: 100 parts of silicon carbide micro powder, 2 parts of boron carbide micro powder, 10 parts of phenolic resin, 1.5 parts of stearic acid and 1 part of polyacrylic acid.
And then adding the weighed matrix material into 120 parts of deionized water, and carrying out ball milling in a roller ball mill for 12 hours to obtain silicon carbide ceramic slurry.
Spraying and granulating the silicon carbide ceramic slurry by using a centrifugal spray tower to obtain granulated powder; the moisture content of the granulated powder was measured to be 0.8%, and the mass ratio of the granulated powder having a particle size of 60-180 mesh was 96%.
(2) Adding toughening material
Weighing 100 parts of granulation powder, adding 5 parts of chopped carbon fibers with the length of 3.5mm and the tow diameter of 50 mu m, and uniformly mixing by using a vibrating screen.
(3) Impregnation treatment of carbon fiber woven body
100 parts of nano carbon powder, 270 parts of nano silicon powder, 20 parts of polyvinyl alcohol and 3.5 parts of polyvinylpyrrolidone, adding 500 parts of deionized water, and ball-milling in a roller ball mill for 11 hours to prepare the mixture slurry of the nano silicon powder and the nano carbon powder.
Placing a two-dimensional mesh-shaped carbon fiber woven body with a tow diameter of 100 mu m and a mesh length and a mesh width of 3mm and 3mm respectively in mixed slurry for soaking for 5min, wherein the carbon fiber woven body can shake in the slurry in the soaking process, so that the surface of the carbon fiber woven body is fully covered with nano silicon powder and nano carbon powder.
Then placing the carbon fiber woven body in a vacuum drying oven, standing for 10 hours at the temperature of 30 ℃, and then heating to 70 ℃ and drying for 20 hours to dry the carbon fiber woven body; and then, putting the dried carbon fiber woven body into the mixed slurry again for dipping, and repeating the steps of dipping and drying for 3 times to uniformly coat a layer of nano silicon powder and nano carbon powder on the surface of the dried carbon fiber woven body.
(4) Preforming of abrasive disk blanks
Firstly paving a layer of silicon carbide granulation powder containing short carbon fibers with the thickness of 40mm in a stainless steel mould with the inner diameter of 600mm on a vibration platform, then paving a soaked carbon fiber woven body, vertically tamping up and down in a mesh of the carbon fiber woven body by using a blunt metal rod with the tip diameter of 5mm, vibrating and flattening, paving a layer of silicon carbide granulation powder added with the short carbon fibers with the thickness of 20mm, paving a soaked carbon fiber woven body, vertically tamping up and down in the mesh of the woven body by using a blunt metal rod with the tip diameter of 5mm, vibrating and flattening; laying a layer of silicon carbide granulation powder with the thickness of 20mm and added with short carbon fibers, laying the impregnated carbon fiber braided body, vertically tamping the carbon fiber braided body up and down in the mesh of the braided body by using a blunt metal rod with the tip diameter of 5mm, and vibrating and compacting and flattening; then, a layer of silicon carbide granulation powder mixed with the short carbon fibers and having a thickness of 40mm is paved, a blunt metal rod with a tip diameter of 5mm is used for vertically tamping up and down in meshes of the woven body, and the woven body is vibrated to compact and flatten.
And performing compression molding on the mold after the vibration compaction and the flattening to obtain a preformed blank of the grinding disc, and performing cold isostatic pressing on the preformed blank after packaging and vacuumizing, wherein the pressure of the cold isostatic pressing is 140MPa, and the pressure maintaining time is 10 min.
(5) Machining of abrasive disk blanks
Drying the grinding disc blank formed by cold isostatic pressing for 10 hours at the temperature of 100 ℃; and then turning to obtain a cylinder with an outer diameter of 580mm, a thickness of 70mm and two planar upper and lower surfaces. A plurality of rows of concentric circular grooves are machined in one plane of the cylinder, the depth of each groove is 3mm, the width of each groove is 1.5mm, and the distance between the grooves is 10 mm.
(6) Sintering of abrasive disk blanks
And placing the processed grinding disc blank in a vacuum sintering furnace, heating to 1600 ℃, preserving the temperature for 1.5 hours to enable the nano silicon powder and the nano carbon powder coated on the carbon fiber woven body to react in situ to generate silicon carbide, improving the interface bonding strength of the carbon fiber and the silicon carbide ceramic matrix, and sintering at 2180 ℃ for 3 hours to obtain the grinding disc sintered body.
(7) Manufacture of abrasive discs
And grinding, lapping and polishing the sintered body of the lapping disc to obtain the silicon carbide ceramic lapping disc with required specification, shape, size and flatness.
Through detection, the obtained silicon carbide ceramic grinding disc has the relative density of 98.2 percent, the Vickers microhardness of 24.1GPa, the three-point bending strength of 580.4MPa and the fracture toughness of 7.4 MPa.m1/2
Example 3
A method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc comprises the following steps:
(1) preparation of granulated powder
Weighing the matrix materials according to the proportion: 100 parts of silicon carbide micro powder, 3 parts of boron carbide micro powder, 15 parts of phenolic resin, 3 parts of fatty glyceride and 2 parts of tetramethyl ammonium hydroxide.
And then adding the weighed matrix material into 150 parts of deionized water, and carrying out ball milling in a roller ball mill for 8 hours to obtain the silicon carbide ceramic slurry.
Spraying and granulating the silicon carbide ceramic slurry by using a centrifugal spray tower to obtain granulated powder; the moisture content of the granulated powder was measured to be 0.8%, and the mass ratio of the granulated powder having a particle size of 60-180 mesh was 96.2%.
(2) Adding toughening material
Weighing 100 parts of granulation powder, adding 4 parts of chopped carbon fibers with the length of 5mm and the tow diameter of 70 mu m, and uniformly mixing by using a vibrating screen.
(3) Impregnation treatment of carbon fiber woven body
100 parts of nano carbon powder, 270 parts of nano silicon powder, 20 parts of polyvinyl alcohol and 3.5 parts of polyvinylpyrrolidone, adding 500 parts of deionized water, and ball-milling for 15 hours in a roller ball mill to prepare the mixture slurry of the nano silicon powder and the nano carbon powder.
The two-dimensional mesh-shaped structure carbon fiber woven body with the tow diameter of 100 mu m, the length and the width of the mesh of which are respectively 50mm and 50mm, is placed in mixed slurry for soaking for 5min, the carbon fiber woven body can shake in the slurry in the soaking process, so that the surface of the carbon fiber woven body is fully distributed with nano silicon powder and nano carbon powder, and the mixed slurry is prepared by mixing the nano carbon powder, the nano silicon powder, a binder, a dispersing agent and deionized water through wet ball milling for 20 hours.
Then placing the carbon fiber woven body in a vacuum drying oven, placing the carbon fiber woven body for 5 hours at the temperature of 35 ℃, and then heating the carbon fiber woven body to 80 ℃ for drying for 10 hours to dry the carbon fiber woven body; and then, putting the dried carbon fiber woven body into the mixed slurry again for dipping, and repeating the steps of dipping and drying for 3 times to uniformly coat a layer of nano silicon powder and nano carbon powder on the surface of the dried carbon fiber woven body.
(4) Preforming of abrasive disk blanks
Firstly paving a layer of silicon carbide granulation powder containing short carbon fibers with the thickness of 40mm in a stainless steel mould with the inner diameter of 600mm on a vibration platform, then paving a soaked carbon fiber woven body, vertically tamping up and down in a mesh of the carbon fiber woven body by using a blunt metal rod with the tip diameter of 5mm, vibrating and flattening, paving a layer of silicon carbide granulation powder added with the short carbon fibers with the thickness of 20mm, paving a soaked carbon fiber woven body, vertically tamping up and down in the mesh of the woven body by using a blunt metal rod with the tip diameter of 5mm, vibrating and flattening; laying a layer of silicon carbide granulation powder with the thickness of 20mm and added with short carbon fibers, laying the impregnated carbon fiber braided body, vertically tamping the carbon fiber braided body up and down in the mesh of the braided body by using a blunt metal rod with the tip diameter of 5mm, and vibrating and compacting and flattening; then, a layer of silicon carbide granulation powder mixed with the short carbon fibers and having a thickness of 40mm is paved, a blunt metal rod with a tip diameter of 5mm is used for vertically tamping up and down in meshes of the woven body, and the woven body is vibrated to compact and flatten.
And performing compression molding on the mold after the vibration compaction and the flattening to obtain a preformed blank of the grinding disc, and performing cold isostatic pressing on the preformed blank after packaging and vacuumizing, wherein the pressure of the cold isostatic pressing is 200MPa, and the pressure maintaining time is 5 min.
(5) Machining of abrasive disk blanks
Drying the grinding disc blank formed by cold isostatic pressing at 150 ℃ for 8 hours; and then turning to obtain a cylinder with an outer diameter of 580mm, a thickness of 70mm and two planar upper and lower surfaces. A plurality of rows of concentric circular grooves are machined in one plane of the cylinder, the depth of each groove is 3mm, the width of each groove is 1.5mm, and the distance between the grooves is 10 mm.
(6) Sintering of abrasive disk blanks
And placing the processed grinding disc blank in a vacuum sintering furnace, heating to 1550 ℃ and preserving heat for 3 hours to enable the nano silicon powder and the nano carbon powder coated on the carbon fiber woven body to react in situ to generate silicon carbide, so that the interface bonding strength of the carbon fiber and the silicon carbide ceramic matrix is improved, and then sintering at 2200 ℃ for 1 hour to obtain the grinding disc sintered body.
(7) Manufacture of abrasive discs
And grinding, lapping and polishing the sintered body of the lapping disc to obtain the silicon carbide ceramic lapping disc with required specification, shape, size and flatness.
Through detection, the obtained silicon carbide ceramic grinding disc has the relative density of 98.4 percent, the Vickers microhardness of 24.3GPa, the three-point bending strength of 587.1MPa and the fracture toughness of 8.1 MPa-m1/2
Comparative example 1:
a method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc comprises the following steps:
technical solution reference is made to example 1.
The difference is that:
removing the dipping treatment of the carbon fiber woven body in the step (3); and (5) simultaneously removing the pre-forming of the grinding disc blank in the step (4) and laying a carbon fiber braided body layer.
The rest of the procedure was the same as in example 1.
Through detection, the obtained silicon carbide ceramic grinding disc has the relative density of 98.8 percent, the Vickers microhardness of 25.3GPa, the three-point bending strength of 410.1MPa and the fracture toughness of 4.2 MPa.m1/2
Comparative example 2:
a method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc comprises the following steps:
technical solution reference is made to example 1.
The difference is that:
removing the short carbon fiber added in the step (2); in the step (4), a blunt metal rod is not used for vertically ramming up and down in meshes of the braided body.
The rest is the same as in example 1.
Through detection, the obtained silicon carbide ceramic grinding disc has the relative density of 98.5 percent, the Vickers microhardness of 25.0GPa, the three-point bending strength of 560.4MPa and the fracture toughness of 6.7 MPa.m1/2
Comparative example 3:
a method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc comprises the following steps:
technical solution reference is made to example 1.
The difference is that: the dipping treatment of the carbon fiber woven body in the step (3) is removed.
The rest is the same as in example 1.
Through detection, the relative density of the silicon carbide ceramic grinding disc is 96.3 percent, the Vickers microhardness is 22.1GPa, the three-point bending strength is 510.1MPa, and the fracture toughness is 6.8 MPa.m1/2
Comparative example 4:
a method for manufacturing a pressureless sintering silicon carbide ceramic grinding disc comprises the following steps:
technical solution reference is made to example 1.
The difference is that: the carbon fiber woven body is changed into carbon fiber cloth almost without meshes.
The rest is the same as in example 1.
The obtained silicon carbide ceramic grinding disc has poor bonding strength between the ceramic matrix and the carbon fiber cloth, and the ceramic matrix and the carbon fiber cloth are easy to delaminate and peel.
And (4) analyzing results:
1. compared with the comparative example 1, the embodiment 1-3 shows that the two-dimensional carbon fiber braided body can achieve remarkable reinforcing and toughening effects.
2. Compared with the comparative example 2, the embodiment 1-3 shows that the technical scheme of the invention introduces the chopped carbon fibers, and vertically tamps the chopped carbon fibers up and down in the meshes of the braided body by using the blunt metal rod to vertically distribute part of the chopped carbon fibers, thereby achieving the effects of strengthening and toughening.
3. Compared with the comparative example 3, the embodiment 1-3 shows that the technical scheme of the invention can improve the interface bonding strength of the carbon fiber and the silicon carbide ceramic matrix by coating the nano silicon component and the nano carbon powder on the carbon fiber braided body tows and carrying out in-situ reaction to generate the silicon carbide, thereby better playing the role of strengthening and toughening.
4. Compared with the comparative example 4, the embodiment 1-3 shows that the technical scheme of the invention utilizes the carbon fiber woven body with meshes to toughen, is beneficial to the combination of the silicon carbide ceramic matrix and the reinforced carbon fibers, avoids layering, and thus better plays a role in strengthening and toughening.
Finally, the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting, and other modifications or equivalent substitutions made by the technical solutions of the present invention by those of ordinary skill in the art should be covered within the scope of the claims of the present invention as long as they do not depart from the spirit and scope of the technical solutions of the present invention.

Claims (9)

1. The method for manufacturing the pressureless sintered silicon carbide ceramic grinding disc is characterized in that raw materials for preparing the grinding disc comprise a matrix material and a toughening material; the matrix material comprises, by mass, 100 parts of silicon carbide micro powder, 0.5-3 parts of boron carbide micro powder, 5-15 parts of adhesive, 0.5-3 parts of surfactant and 0.5-2 parts of dispersant; the toughening material is carbon fiber and a carbon fiber woven body, and the addition amount of the carbon fiber is 0-15% of the total amount of the matrix material;
the manufacturing method specifically comprises the following steps:
(1) preparation of granulated powder
Weighing the matrix material according to the proportion, adding deionized water, wherein the using amount of the deionized water is 0.9-1.5 times of the mass of the silicon carbide micro powder, and then performing ball milling for 8-20 hours to prepare silicon carbide ceramic slurry; then, carrying out spray granulation on the silicon carbide ceramic slurry to obtain granulated powder; the water content of the granulated powder is 0.5-1.2%, and the mass ratio of the granulated powder with the granularity of 60-180 meshes is more than 95%;
(2) adding toughening material
Adding short carbon fibers into the granulated powder, and mixing by using a vibrating screen;
(3) impregnation treatment of carbon fiber woven body
Weaving carbon fibers into a carbon fiber woven body with a two-dimensional mesh structure, wherein the length and the width of meshes of the carbon fiber woven body are respectively 3-50mm and 3-50 mm; then dipping the carbon fiber bundles in the mixed slurry to ensure that the surface of the carbon fiber bundles is fully distributed with the mixed slurry, wherein the mixed slurry is prepared by mixing nano carbon powder, nano silicon powder, a binder, a dispersing agent and deionized water by wet ball milling for 8-20 hours;
then placing the carbon fiber woven body in a vacuum drying oven, placing the carbon fiber woven body for 5-20h at the temperature of 25-35 ℃, and then heating to 60-80 ℃ for drying for 10-30h to dry the carbon fiber woven body; soaking the dried carbon fiber woven body in the mixed slurry again, and repeating the steps for multiple times to uniformly coat a layer of mixed slurry on the surface of the dried carbon fiber woven body;
(4) preforming of abrasive disk blanks
Laying a layer of silicon carbide granulation powder added with short carbon fibers in a mould, compacting and flattening the silicon carbide granulation powder on a vibration platform, laying a soaked carbon fiber woven body, laying a layer of silicon carbide granulation powder added with short carbon fibers, and vertically tamping the carbon fiber woven body by using a blunt metal rod, wherein the tip diameter of the metal rod is smaller than the mesh size of the carbon fiber woven body;
performing compression molding on the mold after the vibration and flattening to obtain a preformed blank of the grinding disc, and performing cold isostatic pressing on the preformed blank after packaging and vacuumizing, wherein the pressure of the cold isostatic pressing is 120-250MPa, and the pressure maintaining time is 5-30 min;
(5) machining of abrasive disk blanks
Drying the grinding disc blank formed by cold isostatic pressing at 80-150 ℃ for 8-20 hours; then turning to obtain a flat surface and required appearance and size, and machining a groove with required shape and size on the working surface according to the requirement;
(6) sintering of abrasive disk blanks
Placing the processed grinding disc blank in a vacuum sintering furnace, heating to 1450-;
(7) manufacture of abrasive discs
And grinding, lapping and polishing the sintered body of the lapping disc to obtain the silicon carbide ceramic lapping disc with required specification, shape, size and flatness.
2. The method for manufacturing the pressureless sintered silicon carbide ceramic grinding disc according to claim 1, wherein the carbon fiber woven body and the chopped carbon fibers are high-strength carbon fibers, and the tensile strength of the high-strength carbon fibers is not less than 2500 MPa; wherein the length of the chopped carbon fiber is 3-5mm, and the diameter of the tow is less than 100 mu m; the diameter of the carbon fiber braided body tows is less than 200 mu m.
3. The method for manufacturing the pressureless sintered silicon carbide ceramic grinding disk according to claim 1, wherein D is the fine silicon carbide powder500.45. + -. 0.2. mu.m.
4. The method for manufacturing the pressureless sintered silicon carbide ceramic grinding disk according to claim 1, wherein the boron carbide micro powder D is obtained by grinding a silicon carbide ceramic material50Is 1.50 +/-1 mu m.
5. The method of claim 1, wherein the surfactant is stearic acid or fatty glyceride; the dispersant is tetramethyl ammonium hydroxide or polyacrylic acid.
6. The method of claim 1, wherein the binder is phenolic resin, polyvinyl alcohol, or carboxymethyl cellulose.
7. The method for manufacturing the pressureless sintered silicon carbide ceramic grinding disk according to claim 1, wherein the molar ratio of the nano carbon powder to the nano silicon powder in the step (3) is 1: 1.05-1.25 percent, the addition amount of the binder is 2-10 percent of the total mass of the nano carbon powder and the nano silicon powder, the addition amount of the dispersant is 0.5-3 percent of the total mass of the nano carbon powder and the nano silicon powder, and the ratio of the deionized water to the total mass of the nano carbon powder and the nano silicon powder is 1.0-2.0: 1; wherein D of the nano carbon powder and the nano silicon powder50Are not more than 100 nm.
8. The method for manufacturing the pressureless sintered silicon carbide ceramic grinding disk according to claim 1, wherein the dispersant in the step (3) is polyvinylpyrrolidone or tetramethylammonium hydroxide.
9. The method for manufacturing the pressureless sintered silicon carbide ceramic grinding disk according to claim 1, wherein the binder in the step (3) is polyvinyl alcohol or carboxymethyl cellulose.
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