阅读说明：本技术 碳陶材料生产设备及其生产工艺 (Carbon-ceramic material production equipment and production process thereof ) 是由 张洪波 于 2021-05-31 设计创作，主要内容包括：本发明属于炭陶材料搅拌和浇注技术领域,尤其是碳陶材料生产设备及其生产工艺,针对现有的碳陶材料生产设备及其生产工艺,没有对物料进行混合搅拌的功能,同时没有对模具进行浇注的功能的问题,现提出如下方案,其包括混合箱,所述混合箱内设有搅拌机构,混合箱的下方设有浇注机构和降温机构,搅拌机构包括隔板、主动转轴、大齿轮、第一搅拌杆、第二搅拌杆、两个搅拌叶、第一被动齿轮、第二被动齿轮、第一圆锥齿轮、隔箱、浇注管、阀门、进料管和第一电机,所述隔板、主动转轴、大齿轮、第一搅拌杆、第二搅拌杆、两个搅拌叶、第一被动齿轮。本发明结构简单,在对物料进行搅拌的同时可对模具浇注,方便人们使用。(The invention belongs to the technical field of carbon ceramic material stirring and pouring, in particular to carbon ceramic material production equipment and a production process thereof, and aims at solving the problems that the existing carbon ceramic material production equipment and the existing production process thereof do not have the functions of mixing and stirring materials and pouring a mold. The invention has simple structure, can pour the mould while stirring the materials and is convenient for people to use.)

1. Carbon pottery material production equipment comprises a mixing box (1) and is characterized in that a stirring mechanism is arranged in the mixing box (1), a pouring mechanism and a cooling mechanism are arranged below the mixing box (1), the stirring mechanism comprises a partition plate (2), a driving rotating shaft (3), a large gear (4), a first stirring rod (5), a second stirring rod (6), two stirring blades (7), a first driven gear (8), a second driven gear (9), a first conical gear (10), a partition box (11), a pouring pipe (12), a valve (13), a feeding pipe (14) and a first motor (15), the partition plate (2), the driving rotating shaft (3), the large gear (4), the first stirring rod (5), the second stirring rod (6), the two stirring blades (7), the first driven gear (8), the second driven gear (9), the first conical gear (10) and the partition box (11) are all located in the mixing box (1), the baffle (2) is fixedly connected with the mixing box (1), the driving rotating shaft (3) is rotatably connected with the inner wall of the top of the mixing box (1), the gear wheel (4) is fixedly connected with one end of the driving rotating shaft (3), the first stirring rod (5) and the second stirring rod (6) are both rotatably connected with the baffle (2), the two stirring blades (7) are fixedly connected with the first stirring rod (5) and the second stirring rod (6), the first driven gear (8) and the second driven gear (9) are both meshed with the gear wheel (4), the first conical gear (10) is fixedly connected with the driving rotating shaft (3), the top inner wall of the mixing box (11) and the mixing box (1) is fixedly connected, the partition pipe (12) is arranged at the bottom of the mixing box (1), on pouring tube (12) was located in valve (13), mixing box (1) right side was located in inlet pipe (14), the top of mixing box (1) was located in first motor (15), the output shaft and initiative pivot (3) fixed connection of first motor (15), pouring mechanism includes first bull stick (16), second conical gear (17), first synchronizing wheel (18), second bull stick (19), second synchronizing wheel (20), hold-in range (21), pendulum rod (22), supplementary bull stick (23), column spinner (24), kelly (25), mould dish (26) and work box (32), the bottom of mixing box (1) is located in work box (32), first bull stick (16), second conical gear (17), first synchronizing wheel (18), second bull stick (19), second synchronizing wheel (20), hold-in range (21), pendulum rod (22), supplementary bull stick (23), column spinner (24), Two kellies (25), mould dish (26) all are located work box (32), and cooling mechanism includes heater (27), rotation post (28), connecting rod (29), refrigerator (30) and second motor (31), and the right side of work box (32) is equipped with out the mouth.

2. The carbon-ceramic material production equipment as claimed in claim 1, wherein the first rotating rod (16) is rotatably connected with the left side of the mixing box (1), the second conical gear (17) is fixedly connected with the first rotating rod (16), the second conical gear (17) is meshed with the first conical gear (10), the first synchronizing wheel (18) is fixedly connected with one end of the first rotating rod (16), the second rotating rod (19) is rotatably connected with the left side of the working box (32), the second synchronizing wheel (20) is fixedly connected with the second rotating rod (19), and the synchronous belt (21) is in transmission connection with the first synchronizing wheel (18) and the second synchronizing wheel (20).

3. The carbon-ceramic material production equipment as claimed in claim 1, wherein the swing rod (22) is fixedly connected with one end of the second rotating rod (19), the auxiliary rotating rod (23) is rotatably connected with the working box (32), the rotating column (24) is fixedly connected with the auxiliary rotating rod (23), a rotating groove is formed in the rotating column (24), one end of the swing rod (22) is located in the rotating groove, the two clamping rods (25) are both fixedly connected with the top of the rotating column (24), and the mold disc (26) is arranged on the two clamping rods (25).

4. The carbon-ceramic material production equipment as claimed in claim 1, wherein the heater (27), the rotating column (28), the connecting rod (29) and the refrigerator (30) are all located in the working box (32), the heater (27) is arranged on the inner wall of the bottom of the working box (32), and the rotating column (28) is rotatably connected with the inner wall of the top of the working box (32).

5. The carbon-ceramic material production equipment as claimed in claim 1, wherein the connecting rod (29) is fixedly connected with one end of the rotating column (28), and the refrigerating machine (30) is fixedly connected with one end of the connecting rod (29).

6. The carbon-ceramic material production equipment as claimed in claim 1, wherein the second motor (31) is arranged at the top of the working box (32), and an output shaft of the second motor (31) is fixedly connected with the rotating column (28).

7. The production process of the carbon ceramic material is characterized by comprising the following steps:

s1: preparing carbon ceramic material production equipment;

s2: adding the micro silicon powder, the epoxy resin, the solvent oil and the polyethyleneimine into carbon ceramic material production equipment, and mixing and stirring by using a stirring mechanism;

s3: injecting the mixed materials into a mould disc by using a pouring mechanism, and placing the mould disc on a heating machine for heating for 20 minutes at the temperature of 120-130 ℃;

s4: cooling and plasticizing the formed material in the die by using a cooling mechanism;

s5: and after cooling, taking out the caking materials through the taking-out port, and inspecting and packaging.

8. A carbon ceramic material production process as claimed in claim 7, wherein the silica fume, epoxy resin, solvent oil and polyethyleneimine in the step S2 are poured into the carbon ceramic material production equipment in the step S1 according to a certain proportion, water is added, and a stirring mechanism is started to work.

9. The carbon-ceramic material production process of claim 7, wherein in the step S3, the stirred material uniformly flows into the mold disc through the pouring pipe, and the mold disc is placed on a heating machine to be heated for 20min, wherein the heating temperature is 120-130 ℃.

10. A carbon-ceramic material production process as claimed in claim 7, wherein the dynamic cooling mechanism in S4 cools the agglomerated materials in the mold disc, and after cooling, the agglomerated materials are taken out through the take-out port, inspected and packaged.

Technical Field

The invention relates to the technical field of carbon ceramic material stirring and pouring, in particular to carbon ceramic material production equipment and a production process thereof.

Background

The carbon-ceramic composite brake material (carbon ceramic for short) is a new type composite material formed by using high-strength carbon fiber as reinforcement and using two phases or multiple phases of pyrolytic carbon and silicon carbide as matrixes, integrates the advantages of powder metallurgy brake material and C/C brake material, effectively overcomes the defects of the two materials, has the advantages of light weight, high specific strength, large specific heat, stable friction property, stable mechanical property and the like, particularly has high impact toughness and strong seawater and salt mist corrosion resistance, and the preparation method of the carbon-ceramic composite material mainly comprises the following steps: 1. hot pressing sintering method, 2, chemical gas phase permeation, 3, polymer precursor impregnation pyrolysis and the like.

The existing carbon ceramic material production equipment and the production process thereof have no function of mixing and stirring materials and no function of pouring a mold.

Disclosure of Invention

The invention aims to solve the defects that the existing carbon ceramic material production equipment and the existing carbon ceramic material production process have no functions of mixing and stirring materials and pouring a mould, and provides the carbon ceramic material production equipment and the carbon ceramic material production process.

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

carbon pottery material production equipment comprises a mixing box, wherein a stirring mechanism is arranged in the mixing box, a pouring mechanism and a cooling mechanism are arranged below the mixing box, the stirring mechanism comprises a partition plate, a driving rotating shaft, a gear wheel, a first stirring rod, a second stirring rod, two stirring blades, a first driven gear, a second driven gear, a first conical gear, a partition box, a pouring pipe, a valve, a feeding pipe and a first motor, the partition plate, the driving rotating shaft, the gear wheel, the first stirring rod, the second stirring rod, the two stirring blades, the first driven gear, the second driven gear, the first conical gear and the partition box are all positioned in the mixing box, the partition plate is fixedly connected with the mixing box, the driving rotating shaft is rotatably connected with the inner wall of the top of the mixing box, the gear wheel is fixedly connected with one end of the driving rotating shaft, the first stirring rod and the second stirring rod are rotatably connected with the partition plate, the two stirring blades are fixedly connected with the first stirring rod and the second stirring rod, the first driven gear and the second driven gear are fixedly connected with the first stirring rod and the second stirring rod, the first driven gear and the second driven gear are meshed with the gear wheel, the first conical gear is fixedly connected with the driving rotating shaft, the partition box is fixedly connected with the inner wall of the top of the mixing box, the pouring pipe is arranged at the bottom of the mixing box, the valve is arranged on the pouring pipe, the feeding pipe is arranged on the right side of the mixing box, the first motor is arranged at the top of the mixing box, the output shaft of the first motor is fixedly connected with the driving rotating shaft, the pouring mechanism comprises a first rotating rod, a second conical gear, a first synchronizing wheel, a second rotating rod, a second synchronizing wheel, a synchronous belt, a swing rod, an auxiliary rotating rod, a rotating column, a clamping rod, a mold disc and a working box, the working box is arranged at the bottom of the mixing box, the first rotating rod, the second conical gear, the first synchronizing wheel, the second rotating rod, the second synchronizing wheel, the synchronous belt, the swing rod, the first synchronizing wheel, the second synchronizing wheel, the swing rod, the second synchronizing wheel, the second synchronizing belt, the swing rod, the valve, The auxiliary rotating rod, the rotating column, the two clamping rods and the die disc are all located in the working box, the cooling mechanism comprises a heating machine, the rotating column, a connecting rod, a refrigerating machine and a second motor, and a taking-out opening is formed in the right side of the working box.

Preferably, the first rotating rod is connected with the left side of the mixing box in a rotating mode, the second bevel gear is fixedly connected with the first rotating rod, the second bevel gear is meshed with the first bevel gear, the first synchronizing wheel is fixedly connected with one end of the first rotating rod, the second rotating rod is connected with the left side of the working box in a rotating mode, the second synchronizing wheel is fixedly connected with the second rotating rod, and the synchronous belt is in transmission connection with the first synchronizing wheel and the second synchronizing wheel.

Preferably, the swing rod is fixedly connected with one end of the second rotating rod, the auxiliary rotating rod is connected with the working box in a rotating mode, the rotating column is fixedly connected with the auxiliary rotating rod, a rotating groove is formed in the rotating column, one end of the swing rod is located in the rotating groove, the two clamping rods are fixedly connected with the top of the rotating column, and the die disc is arranged on the two clamping rods.

Preferably, the heater, the rotating column, the connecting rod and the refrigerator are all located in the working box, the heater is arranged on the inner wall of the bottom of the working box, and the rotating column is rotatably connected with the inner wall of the top of the working box.

Preferably, the connecting rod is fixedly connected with one end of the rotating column, and the refrigerator is fixedly connected with one end of the connecting rod.

Preferably, the second motor is arranged at the top of the working box, and an output shaft of the second motor is fixedly connected with the rotating column.

A production process of a carbon ceramic material comprises the following steps:

s1: preparing carbon ceramic material production equipment;

s2: mixing and stirring the micro silicon powder, the epoxy resin, the solvent oil and the polyethyleneimine by a stirring mechanism;

s3: pouring the mixed materials into a mould disc by a pouring mechanism, and placing the mould disc on a heating machine for heating for 20 minutes at the temperature of 120-130 ℃;

s4: and the cooling mechanism cools and plasticizes the formed material in the die.

S5: and after cooling, taking out the caking materials through the taking-out port, and inspecting and packaging.

Preferably, the silica fume, the epoxy resin, the solvent oil and the polyethyleneimine in the step S2 are poured into the carbon ceramic material production equipment in the step S1 according to a certain proportion, water is added, and a stirring mechanism is started to work.

Preferably, in S3, the stirred material flows uniformly into the mold disc through the pouring tube, and the mold disc is placed on a heating machine to be heated for 20min, wherein the heating temperature is 120 ℃ to 130 ℃.

Preferably, in S4, the movable cooling mechanism cools the agglomerated material in the mold tray, and after cooling, the agglomerated material is taken out through the take-out port, and is inspected and packaged.

Compared with the prior art, the invention has the advantages that:

(1) this scheme is owing to set up the initiative pivot and drive the gear wheel and rotate, and the gear wheel drives first driven gear and second driven gear and rotates, and first driven gear and second driven gear drive first puddler and second puddler and rotate, and first puddler and second puddler rotate and drive two stirring leaves and stir the mixture to the material, have realized the purpose that the stirring was mixed.

(2) This scheme has owing to set up first bull stick and has driven first synchronizing wheel and rotate, and first synchronizing wheel passes through the hold-in range and drives the second synchronizing wheel and rotate, and the second synchronizing wheel drives the second bull stick and rotates, and the second bull stick drives the pendulum rod rotation, and the pendulum rod reciprocates and drives the column spinner and rotate, and the column spinner drives the mould dish through two kellies and rotates, has realized carrying out the purpose of pouring to the mould.

The stirring device is simple in structure and convenient to use, can be used for pouring a mold while stirring materials, and is convenient for people to use.

Drawings

FIG. 1 is a schematic structural diagram of a carbon ceramic material production facility and a production process thereof according to the present invention;

FIG. 2 is a schematic side view of the swing rod and the rotating column of the carbon ceramic material production equipment and the production process thereof;

FIG. 3 is a schematic structural diagram of part A of the carbon ceramic material production equipment and the production process thereof according to the present invention;

FIG. 4 is a schematic perspective view of a spin column of the carbon ceramic material production apparatus and the production process thereof according to the present invention;

fig. 5 is a schematic perspective view of a mold plate of the carbon ceramic material production apparatus and the production process thereof according to the present invention.

In the figure: 1. a mixing box; 2. a partition plate; 3. a driving rotating shaft; 4. a bull gear; 5. a first stirring rod; 6. a second stirring rod; 7. stirring blades; 8. a first driven gear; 9. a second driven gear; 10. a first conical gear; 11. separating the box; 12. a pouring tube; 13. a valve; 14. a feed pipe; 15. a first motor; 16. a first rotating lever; 17. a second conical gear; 18. a first synchronizing wheel; 19. a second rotating rod; 20. a second synchronizing wheel; 21. a synchronous belt; 22. a swing rod; 23. an auxiliary rotating rod; 24. a spin column; 25. a clamping rod; 26. a mold plate; 27. a heater; 28. rotating the column; 29. a connecting rod; 30. a refrigerator; 31. a second motor; 32. a work box.

Detailed Description

The technical solution in this embodiment will be clearly and completely described below with reference to the drawings in this embodiment.

Example 1

Referring to fig. 1-5, a carbon ceramic material production apparatus comprises a mixing box 1, a stirring mechanism is arranged in the mixing box 1, a pouring mechanism and a cooling mechanism are arranged below the mixing box 1, the stirring mechanism comprises a partition plate 2, a driving rotating shaft 3, a large gear 4, a first stirring rod 5, a second stirring rod 6, two stirring blades 7, a first driven gear 8, a second driven gear 9, a first conical gear 10, a partition box 11, a pouring pipe 12, a valve 13, a feeding pipe 14 and a first motor 15, the partition plate 2, the driving rotating shaft 3, the large gear 4, the first stirring rod 5, the second stirring rod 6, the two stirring blades 7, the first driven gear 8, the second driven gear 9, the first conical gear 10 and the partition box 11 are all located in the mixing box 1, the partition plate 2 is fixedly connected with the mixing box 1, the driving rotating shaft 3 is rotatably connected with the inner wall of the top of the mixing box 1, the large gear 4 is fixedly connected with one end of the driving rotating shaft 3, the first stirring rod 5 and the second stirring rod 6 are both rotationally connected with the partition board 2, the two stirring blades 7 are fixedly connected with the first stirring rod 5 and the second stirring rod 6, the first driven gear 8 and the second driven gear 9 are both meshed with the large gear 4, the first conical gear 10 is fixedly connected with the driving rotating shaft 3, the partition box 11 is fixedly connected with the inner wall of the top of the mixing box 1, the pouring pipe 12 is arranged at the bottom of the mixing box 1, the valve 13 is arranged on the pouring pipe 12, the feeding pipe 14 is arranged at the right side of the mixing box 1, the first motor 15 is arranged at the top of the mixing box 1, the output shaft of the first motor 15 is fixedly connected with the driving rotating shaft 3, the pouring mechanism comprises a first rotating rod 16, a second conical gear 17, a first synchronizing wheel 18, a second rotating rod 19, a second synchronizing wheel 20, a synchronizing belt 21, The swing rod 22, the auxiliary rotating rod 23, the rotary column 24, the clamping rod 25, the mold disc 26 and the working box 32, the working box 32 is arranged at the bottom of the mixing box 1, the first rotating rod 16, the second conical gear 17, the first synchronizing wheel 18, the second rotating rod 19, the second synchronizing wheel 20, the synchronous belt 21, the swing rod 22, the auxiliary rotating rod 23, the rotary column 24, the two clamping rods 25 and the mold disc 26 are all located in the working box 32, the cooling mechanism comprises a heater 27, a rotary column 28, a connecting rod 29, a refrigerator 30 and a second motor 31, and a taking-out opening is formed in the right side of the working box 32.

In this embodiment, the first rotating rod 16 is rotatably connected to the left side of the mixing box 1, the second bevel gear 17 is fixedly connected to the first rotating rod 16, the second bevel gear 17 is engaged with the first bevel gear 10, the first synchronizing wheel 18 is fixedly connected to one end of the first rotating rod 16, the second rotating rod 19 is rotatably connected to the left side of the working box 32, the second synchronizing wheel 20 is fixedly connected to the second rotating rod 19, and the synchronous belt 21 is in transmission connection with the first synchronizing wheel 18 and the second synchronizing wheel 20.

In this embodiment, the swing rod 22 is fixedly connected to one end of the second rotating rod 19, the auxiliary rotating rod 23 is rotatably connected to the working box 32, the rotating column 24 is fixedly connected to the auxiliary rotating rod 23, a rotating groove is formed in the rotating column 24, one end of the swing rod 22 is located in the rotating groove, the two clamping rods 25 are both fixedly connected to the top of the rotating column 24, and the mold disc 26 is disposed on the two clamping rods 25.

In this embodiment, the heater 27, the rotary column 28, the connecting rod 29, and the refrigerator 30 are all located in the operating box 32, the heater 27 is disposed on the bottom inner wall of the operating box 32, and the rotary column 28 is rotatably connected to the top inner wall of the operating box 32.

In this embodiment, the connecting rod 29 is fixedly connected to one end of the rotary column 28, and the refrigerator 30 is fixedly connected to one end of the connecting rod 29.

In this embodiment, the second motor 31 is disposed at the top of the working box 32, and an output shaft of the second motor 31 is fixedly connected to the rotating column 28.

A production process of a carbon ceramic material comprises the following steps:

s1: preparing carbon ceramic material production equipment;

s2: mixing and stirring the micro silicon powder, the epoxy resin, the solvent oil and the polyethyleneimine by a stirring mechanism;

s3: the pouring mechanism injects the mixed materials into a mould disc, and the mould disc is placed on a heating machine to be heated for 20 minutes at the temperature of 120-130 ℃;

s4: and the cooling mechanism cools and plasticizes the formed material in the die.

S5: and after cooling, taking out the caking materials through the taking-out port, and inspecting and packaging.

In this embodiment, the silica fume, the epoxy resin, the solvent oil and the polyethyleneimine in the step S2 are poured into the carbon ceramic material production equipment in the step S1 according to a certain proportion, water is added, and the stirring mechanism is started to work.

In this embodiment, in S3, the stirred material uniformly flows into the mold disk through the pouring tube, and the mold disk is placed on a heater to be heated for 20min at a temperature of 120 ℃ to 130 ℃.

In this embodiment, in S4, the movable cooling mechanism cools the agglomerated material in the die tray, and after cooling, the agglomerated material is taken out through the take-out port, and is inspected and packaged.

Example 2

Referring to fig. 1-5, a carbon ceramic material production device comprises a mixing box 1, a stirring mechanism is arranged in the mixing box 1, a pouring mechanism and a cooling mechanism are arranged below the mixing box 1, the stirring mechanism comprises a partition plate 2, a driving rotating shaft 3, a large gear 4, a first stirring rod 5, a second stirring rod 6, two stirring blades 7, a first driven gear 8, a second driven gear 9, a first conical gear 10, a partition box 11, a pouring pipe 12, a valve 13, a feeding pipe 14 and a first motor 15, the partition plate 2, the driving rotating shaft 3, the large gear 4, the first stirring rod 5, the second stirring rod 6, the two stirring blades 7, the first driven gear 8, the second driven gear 9, the first conical gear 10 and the partition box 11 are all located in the mixing box 1, the partition plate 2 is welded to the mixing box 1, the driving rotating shaft 3 is rotatably connected to the inner wall of the top of the mixing box 1, the large gear 4 is welded to one end of the driving rotating shaft 3, the first stirring rod 5 and the second stirring rod 6 are rotatably connected with the partition board 2, the two stirring blades 7 are welded with the first stirring rod 5 and the second stirring rod 6, the first driven gear 8 and the second driven gear 9 are engaged with the large gear 4, the first conical gear 10 is welded with the driving rotating shaft 3, the partition box 11 is welded with the inner wall of the top of the mixing box 1, the pouring pipe 12 is arranged at the bottom of the mixing box 1, the valve 13 is arranged on the pouring pipe 12, the feeding pipe 14 is arranged at the right side of the mixing box 1, the first motor 15 is arranged at the top of the mixing box 1, the output shaft of the first motor 15 is welded with the driving rotating shaft 3, the pouring mechanism comprises a first rotating rod 16, a second conical gear 17, a first synchronizing wheel 18, a second rotating rod 19, a second synchronizing wheel 20, a synchronizing belt 21, The swing rod 22, the auxiliary rotating rod 23, the rotary column 24, the clamping rod 25, the mold disc 26 and the working box 32, the working box 32 is arranged at the bottom of the mixing box 1, the first rotating rod 16, the second conical gear 17, the first synchronizing wheel 18, the second rotating rod 19, the second synchronizing wheel 20, the synchronous belt 21, the swing rod 22, the auxiliary rotating rod 23, the rotary column 24, the two clamping rods 25 and the mold disc 26 are all located in the working box 32, the cooling mechanism comprises a heater 27, a rotary column 28, a connecting rod 29, a refrigerator 30 and a second motor 31, and a taking-out opening is formed in the right side of the working box 32.

In this embodiment, the first rotating rod 16 is rotatably connected to the left side of the mixing box 1, the second bevel gear 17 is connected to the first rotating rod 16 in a welding manner, the second bevel gear 17 is engaged with the first bevel gear 10, the first synchronizing wheel 18 is connected to one end of the first rotating rod 16 in a welding manner, the second rotating rod 19 is connected to the left side of the working box 32 in a rotating manner, the second synchronizing wheel 20 is connected to the second rotating rod 19 in a welding manner, the synchronous belt 21 is in transmission connection with the first synchronizing wheel 18 and the second synchronizing wheel 20, and the first synchronizing wheel 18 can drive the second synchronizing wheel 20 to rotate through the synchronous belt 21.

In this embodiment, the swing rod 22 is connected with the one end welded connection of the second rotating rod 19, the auxiliary rotating rod 23 is connected with the working box 32 in a rotating manner, the rotating column 24 is connected with the auxiliary rotating rod 23 in a welded manner, a rotating groove is formed in the rotating column 24, one end of the swing rod 22 is located in the rotating groove, the two clamping rods 25 are connected with the top of the rotating column 24 in a welded manner, the mold disc 26 is arranged on the two clamping rods 25, and the rotating column 24 can drive the mold disc 26 to rotate through the two clamping rods 25.

In this embodiment, the heater 27, the rotating column 28, the connecting rod 29 and the refrigerator 30 are all located in the working box 32, the heater 27 is disposed on the inner wall of the bottom of the working box 32, the rotating column 28 is rotatably connected with the inner wall of the top of the working box 32, and the rotating column 28 can drive the refrigerator 30 to rotate through the connecting rod 29.

In this embodiment, the connecting rod 29 is welded to one end of the rotary column 28, and the refrigerator 30 is welded to one end of the connecting rod 29.

In this embodiment, the second motor 31 is disposed at the top of the working box 32, an output shaft of the second motor 31 is welded to the rotating column 28, and the output shaft of the second motor 31 can drive the rotating column 28 to rotate.

A production process of a carbon ceramic material comprises the following steps:

s1: preparing carbon ceramic material production equipment;

s2, mixing and stirring the micro silicon powder, the epoxy resin, the solvent oil and the polyethyleneimine by a stirring mechanism;

s3: the pouring mechanism injects the mixed materials into a mould disc, and the mould disc is placed on a heating machine to be heated for 20 minutes at the temperature of 120-130 ℃;

s4: and the cooling mechanism cools and plasticizes the formed material in the die.

S5: and after cooling, taking out the caking materials through the taking-out port, and inspecting and packaging.

In this embodiment, the silica fume, the epoxy resin, the solvent oil and the polyethyleneimine in the step S2 are poured into the carbon ceramic material production equipment in the step S1 according to a certain proportion, water is added, and the stirring mechanism is started to work, wherein the stirring time is 30 min.

In this embodiment, in S3, the stirred material uniformly flows into the mold disk through the pouring tube, and the mold disk is placed on a heater to be heated for 20min at a temperature of 120 ℃ to 130 ℃.

In this embodiment, in S4, the movable cooling mechanism cools the agglomerated material in the die tray, and after cooling, the agglomerated material is taken out through the take-out port, and is inspected and packaged.

In this embodiment, when the device is used, materials are poured into the mixing box 1 through the feeding pipe 14, the first motor 15 is started, the output shaft of the first motor 15 drives the driving rotating shaft 3 to rotate, the driving rotating shaft 3 drives the large gear 4 to rotate, the large gear 4 drives the first driven gear 8 and the second driven gear 9 to rotate, the first driven gear 8 and the second driven gear 9 drive the first stirring rod 5 and the second stirring rod 6 to rotate, the first stirring rod 5 and the second stirring rod 6 rotate to drive the two stirring blades 7 to stir and mix the materials, meanwhile, the driving rotating shaft 3 drives the second bevel gear 17 to rotate through the first bevel gear 10, the second bevel gear 17 drives the first rotating rod 16 to rotate, the first rotating rod 16 drives the first synchronizing wheel 18 to rotate, the first synchronizing wheel 18 drives the second synchronizing wheel 20 to rotate through the synchronous belt 21, the second synchronizing wheel 20 drives the second rotating rod 19 to rotate, the second rotating rod 19 drives the oscillating rod 22 to rotate, the oscillating rod 22 drives the rotating column 24 to rotate in a reciprocating mode, the rotating column 24 drives the mold disc 26 to rotate through the two clamping rods 25, the valve 13 is opened simultaneously, materials in the mixing box 1 can flow into the mold disc 26 through the pouring pipe 12, the mold disc 26 is taken down after being fully poured, the mold disc 26 is placed on the heating machine 27 to be heated, after the materials are heated into knots, the second motor 31 is started, the output shaft of the second motor 31 drives the rotating column 28 to rotate, the rotating column 28 drives the connecting rod 29 to rotate, the connecting rod 29 drives the refrigerating machine 30 to rotate, and the knots formed materials on the mold disc 26 are cooled.