CN112873496A - Manufacturing device and manufacturing method of ceramic experiment mold - Google Patents

Abstract

The invention discloses a ceramic experiment mould manufacturing device and a manufacturing method thereof, the device comprises a tank body, the bottom of the tank body is fixedly connected with a base, the top of the tank body is fixedly connected with a feeding pipe in a penetrating way, the material to be mixed is added through the feeding pipe, the blade is driven to rotate under the action of the self gravity of the material, so that a rotating shaft is driven to rotate, a transmission gear is driven to rotate through the rotation of the rotating shaft, so that a transmission rod is driven to rotate, the transmission rod drives a second bevel gear to rotate through a first bevel gear, so that the rotating rod rotates, a gear drives a sealing plate to slide inwards along the inner side wall of a sliding groove through the rotation of the rotating rod, when the required material is added, the sealing plate seals the feeding pipe, the quantitative addition of the material is realized, the further mixing of the material is realized through the rotation, the quality and the hardness of the produced die are ensured, the service life of the die is prolonged, and the resources are saved.

Description

Manufacturing device and manufacturing method of ceramic experiment mold

Technical Field

The invention relates to the technical field of ceramic molds, in particular to a manufacturing device and a manufacturing method of a ceramic experiment mold.

Background

The ceramic mould is made of gypsum and can be divided into high-strength gypsum and common gypsum; the high-strength gypsum is mainly used in mechanical pressing production, and because the mechanical pressing has certain pressure, the gypsum mold can have certain impact; ordinary gypsum is mainly used for producing grouting and printing blanks, the requirements of the grouting and printing blanks on the gypsum are not high, in 1877, the vitrified grinding wheel which is made into abrasive only by using clay as a bonding agent in the United states marks the birth of a vitrified mold, in 1930, the selection of an organization number of the vitrified mold is started, in 1970, the vitrified bond cubic boron nitride grinding wheel appears, and after 20 th century and 80 th era, the overseas vitrified mold is developed rapidly and has high technical level; while the ceramic mold in China has been developed from the 20 th century and the 50 th century, the ceramic mold has always been the main part in the total composition of the mold, and although the ceramic mold yield has a trend of decreasing in the total mold yield with the continuous development of the types of the bonding agent materials and the improvement of the types of the molds, the ceramic mold yield still occupies a large proportion in the total mold yield.

Traditional manufacturing installation for ceramic experiment mould, most when carrying out the stirring of material and mixing, can't accomplish the ration of material and add, work efficiency is low moreover, and this can influence the production efficiency of mould, for this reason we propose a ceramic experiment mould manufacturing installation and manufacturing method and solve above-mentioned problem.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides a device and a method for manufacturing a ceramic experimental mold.

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

the utility model provides a pottery experiment mould manufacturing installation, includes a jar body, the bottom fixedly connected with base of the jar body, fixedly connected with inlet pipe is run through at the top of the jar body, the bottom of the jar body runs through fixedly connected with arranges the material pipe, arrange the inside wall fixedly connected with solenoid valve of material pipe, the lateral wall of the jar body runs through the fixedly connected with filling tube, the lateral wall fixedly connected with drive rabbling mechanism of the jar body, the inside wall top fixed connection dead lever of the jar body, the lateral wall through rotation of dead lever is connected with quantitative feeding mechanism.

Preferably, the drive rabbling mechanism include with jar external side wall fixed connection's motor case, the inside wall fixedly connected with driving motor of motor case, driving motor's output shaft fixedly connected with (mixing) shaft, the outside wall fixedly connected with stirring piece of (mixing) shaft, the tip of (mixing) shaft rotates with the inside wall of the jar body to be connected.

Preferably, the quantitative feeding mechanism comprises a rotating shaft which is fixedly connected with the side wall of the fixed rod in a penetrating manner, blades are fixedly connected to the outer side wall of the rotating shaft, a transmission gear is meshed with the outer side wall of the rotating shaft, a transmission rod is fixedly connected to the inner side wall of the transmission rod in a penetrating manner, a first bevel gear is fixedly connected to the top of the transmission rod, a second bevel gear is meshed with the outer side wall of the first bevel gear in a penetrating manner, a rotating rod is fixedly connected to the inner side wall of the second bevel gear in a penetrating manner, a gear is fixedly connected to the outer side wall of the rotating rod in a penetrating manner, a sealing plate is meshed with the outer side wall of the gear, a sliding groove is connected to the outer side wall of the sealing plate in a sealing and sliding manner, the lateral wall of connecting block and the lateral wall fixed connection of inlet pipe, the lateral wall of pivot runs through fixedly connected with vibration filtering mechanism.

Preferably, the vibration filter mechanism includes the special-shaped gear that runs through fixed connection with the pivot lateral wall, the lateral wall intermeshing of special-shaped gear has the connecting rod, the bottom fixedly connected with filter screen of connecting rod, the bottom of filter screen is laminated each other has the fixed block, the lateral wall of filter screen and the sealed sliding connection of the inside wall of the jar body, the lateral wall of fixed block and the inside wall fixed connection of the jar body.

Preferably, the feeding pipe is arranged to be square, and the feeding pipe is arranged to be L-shaped.

Preferably, the outer side wall of the rotating shaft is provided with threads, and the threads arranged on the outer side wall of the rotating shaft are matched with the threads arranged on the outer side wall of the transmission gear.

Preferably, the lateral wall of connecting rod is provided with the tooth, the tooth that the connecting rod lateral wall set up and the tooth looks adaptation that the dysmorphism gear lateral wall set up.

A method for manufacturing a ceramic experimental mold comprises the following steps:

s1: 15-21 parts of high-temperature vinyl resin, 35-49 parts of metallurgical powder black, 27-38 parts of ceramic powder, 8-12 parts of carbon fiber and 15-21 parts of inorganic silicon powder;

s2: sieving the powder with large particles, taking out the powder, and pouring the impurity-free metallurgical powder black, ceramic powder, carbon fiber and inorganic silicon powder into a large container to be fully and uniformly stirred;

s3: adding high-temperature vinyl resin into the powder mixture prepared in the last step, slowly adding the high-temperature vinyl resin while stirring, and fully stirring for one hour to form a paste for later use;

s4: slowly pouring the paste into a prepared model die, immediately heating the model die, keeping the constant temperature for 3 hours after heating to 300 ℃, naturally cooling and die-casting for forming; pressurizing again after one-time die casting molding to ensure that the materials are more compact; heating the mold to 80 ℃ after 2 hours, heating to 150 ℃ again after 3 hours, and keeping the temperature increased by 50 ℃ every hour until the temperature is increased by 300 ℃ and stopping heating; and naturally cooling to obtain the final ceramic die.

Compared with the prior art, the invention has the beneficial effects that:

1. when carrying out the mould manufacturing, add the material that needs mix through the inlet pipe, self action of gravity through the material drives the rotation of blade, and then make the pivot rotate, rotation through the pivot drives drive gear's rotation, and then drives the rotation of transfer line, make the transfer line drive second bevel gear through first bevel gear and rotate, and then make the rotation of bull stick, make the gear drive closing plate along the inside wall of spout inwards slide through the rotation of bull stick, after required material joining is accomplished, the closing plate will seal the inlet pipe, the ration interpolation to the material has been realized, the further mixing of material has been realized through the rotation of blade, mixing efficiency has been improved, the quality and the hardness of producing the mould have been guaranteed, the service life of mould has been prolonged, resources are saved.

2. The rotation through the pivot will drive the rotation with pivot lateral wall through fixed connection's special-shaped gear, and then make the connecting rod drive the filter screen and upwards slide, when the lateral wall of special-shaped gear no longer with the lateral wall intermeshing of connecting rod, the filter screen will slide downwards under the action of gravity of self action of gravity and material, make the top of the bottom striking fixed block of filter screen, realized the abundant filtration to the material, prevent that the material from filtering the not enough condition of mould that leads to inadequately, the qualification rate of mould has been guaranteed to produce, thereby the quality of product through the mould has been protected.

3. When needs carry out with high temperature vinyl's stirring, through starting driving motor, the rotation of drive shaft is driven through driving motor's rotation, and then makes the stirring piece rotate, has realized the intensive mixing to material and high temperature vinyl through the stirring piece that dysmorphism set up, has improved mixing efficiency, has guaranteed the quality of the cream body that the stirring obtained to the quality of mould has been guaranteed.

Drawings

FIG. 1 is a schematic front sectional structural view of a ceramic experimental mold manufacturing apparatus and a manufacturing method thereof according to the present invention;

FIG. 2 is an enlarged schematic structural diagram of the part A in FIG. 1 of the apparatus and the method for manufacturing the experimental ceramic mold according to the present invention;

FIG. 3 is a schematic back structural view of a ceramic experimental mold manufacturing apparatus and a manufacturing method thereof according to the present invention;

FIG. 4 is an enlarged schematic structural diagram of a part B in FIG. 3 of the apparatus and method for manufacturing a ceramic experimental mold according to the present invention;

FIG. 5 is a schematic side view of a gear and a rotating shaft of the apparatus and method for manufacturing a ceramic experimental mold according to the present invention;

fig. 6 is a schematic side structure view of a special-shaped gear and a connecting rod of the device and the method for manufacturing the ceramic experimental mold according to the present invention.

In the figure: 1 tank body, 2 bases, 3 feeding pipes, 4 discharging pipes, 5 electromagnetic valves, 6 feeding pipes, 7 fixing rods, 8 blades, 9 rotating shafts, 10 transmission gears, 11 transmission rods, 12 first bevel gears, 13 second bevel gears, 14 rotating rods, 15 gears, 16 sealing plates, 17 sliding grooves, 18 connecting blocks, 19 special-shaped gears, 20 connecting rods, 21 filter screens, 22 fixing blocks, 23 motor boxes, 24 driving motors, 25 stirring shafts and 26 stirring blades.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

The first embodiment is as follows:

a method for manufacturing a ceramic experimental mold comprises the following steps:

s1: 15 parts of high-temperature vinyl resin, 35 parts of metallurgical powder black, 27 parts of ceramic powder, 8 parts of carbon fiber and 15 parts of inorganic silicon powder;

s2: sieving the powder with large particles, taking out the powder, and pouring the impurity-free metallurgical powder black, ceramic powder, carbon fiber and inorganic silicon powder into a large container to be fully and uniformly stirred;

s3: adding high-temperature vinyl resin into the powder mixture prepared in the last step, slowly adding the high-temperature vinyl resin while stirring, and fully stirring for one hour to form a paste for later use;

s4: slowly pouring the paste into a prepared model die, immediately heating the model die, keeping the constant temperature for 3 hours after heating to 300 ℃, naturally cooling and die-casting for forming; pressurizing again after one-time die casting molding to ensure that the materials are more compact; heating the mold to 80 ℃ after 2 hours, heating to 150 ℃ again after 3 hours, and keeping the temperature increased by 50 ℃ every hour until the temperature is increased by 300 ℃ and stopping heating; and naturally cooling to obtain the final ceramic die.

Example two:

a method for manufacturing a ceramic experimental mold comprises the following steps:

s1: 18 parts of high-temperature vinyl resin, 42 parts of metallurgical powder black, 32 parts of ceramic powder, 10 parts of carbon fiber and 18 parts of inorganic silicon powder;

s2: sieving the powder with large particles, taking out the powder, and pouring the impurity-free metallurgical powder black, ceramic powder, carbon fiber and inorganic silicon powder into a large container to be fully and uniformly stirred;

s3: adding high-temperature vinyl resin into the powder mixture prepared in the last step, slowly adding the high-temperature vinyl resin while stirring, and fully stirring for one hour to form a paste for later use;

s4: slowly pouring the paste into a prepared model die, immediately heating the model die, keeping the constant temperature for 3 hours after heating to 300 ℃, naturally cooling and die-casting for forming; pressurizing again after one-time die casting molding to ensure that the materials are more compact; heating the mold to 80 ℃ after 2 hours, heating to 150 ℃ again after 3 hours, and keeping the temperature increased by 50 ℃ every hour until the temperature is increased by 300 ℃ and stopping heating; and naturally cooling to obtain the final ceramic die.

Example three:

a method for manufacturing a ceramic experimental mold comprises the following steps:

s1: 21 parts of high-temperature vinyl resin, 49 parts of metallurgical powder black, 38 parts of ceramic powder, 12 parts of carbon fiber and 21 parts of inorganic silicon powder;

s2: sieving the powder with large particles, taking out the powder, and pouring the impurity-free metallurgical powder black, ceramic powder, carbon fiber and inorganic silicon powder into a large container to be fully and uniformly stirred;

s3: adding high-temperature vinyl resin into the powder mixture prepared in the last step, slowly adding the high-temperature vinyl resin while stirring, and fully stirring for one hour to form a paste for later use;

s4: slowly pouring the paste into a prepared model die, immediately heating the model die, keeping the constant temperature for 3 hours after heating to 300 ℃, naturally cooling and die-casting for forming; pressurizing again after one-time die casting molding to ensure that the materials are more compact; heating the mold to 80 ℃ after 2 hours, heating to 150 ℃ again after 3 hours, and keeping the temperature increased by 50 ℃ every hour until the temperature is increased by 300 ℃ and stopping heating; and naturally cooling to obtain the final ceramic die.

Referring to fig. 1-6, a ceramic experiment mold manufacturing device comprises a tank body 1, a base 2 is fixedly connected to the bottom of the tank body 1, a feeding pipe 3 is fixedly connected to the top of the tank body 1 in a penetrating manner, a discharging pipe 4 is fixedly connected to the bottom of the tank body 1 in a penetrating manner, an electromagnetic valve 5 is fixedly connected to the inner side wall of the discharging pipe 4, a feeding pipe 6 is fixedly connected to the side wall of the tank body 1 in a penetrating manner, the feeding pipe 3 is square, the feeding pipe 6 is L-shaped, a driving and stirring mechanism is fixedly connected to the outer side wall of the tank body 1 and comprises a motor box 23 fixedly connected to the outer side wall of the tank body 1, a driving motor 24 is fixedly connected to the inner side wall of the motor box 23, a stirring shaft 25 is fixedly connected to an output shaft of the driving motor 24;

when the high-temperature vinyl resin is required to be stirred, the driving motor 24 is started, the driving motor 24 rotates to drive the stirring shaft 25 to rotate, so that the stirring sheet 26 rotates, the materials and the high-temperature vinyl resin are fully mixed through the special-shaped stirring sheet 26, the mixing efficiency is improved, the quality of a paste obtained through stirring is ensured, and the quality of a die is ensured;

the top of the inner side wall of the tank body 1 is fixedly connected with a fixed rod 7, the side wall of the fixed rod 7 is connected with a quantitative feeding mechanism in a penetrating and rotating way, the quantitative feeding mechanism comprises a rotating shaft 9 fixedly connected with the side wall of the fixed rod 7 in a penetrating way, the outer side wall of the rotating shaft 9 is fixedly connected with blades 8, the outer side wall of the rotating shaft 9 is meshed with a transmission gear 10, the outer side wall of the rotating shaft 9 is provided with threads, the threads arranged on the outer side wall of the rotating shaft 9 are matched with the threads arranged on the outer side wall of the transmission gear 10, the inner side wall of the transmission gear 10 is fixedly connected with a transmission rod 11 in a penetrating way, the top of the transmission rod 11 is fixedly connected with a first bevel gear 12, the outer side wall of the first bevel gear 12 is meshed, the outer side wall of the sealing plate 16 is hermetically and slidably connected with a sliding groove 17, the outer side wall of the rotating rod 14 is in penetrating and rotating connection with a connecting block 18, the outer side wall of the transmission rod 11 is in penetrating and rotating connection with the top of the tank body 1, the sliding groove 17 is formed in the side wall of the feeding pipe 3, and the outer side wall of the connecting block 18 is fixedly connected with the outer side wall of the feeding pipe 3;

when a mold is manufactured, materials to be mixed are added through the feeding pipe 3, the blades 8 are driven to rotate under the action of the self gravity of the materials, the rotating shaft 9 is further driven to rotate, the transmission gear 10 is driven to rotate through the rotation of the rotating shaft 9, the transmission rod 11 is further driven to rotate, the transmission rod 11 drives the second bevel gear 13 to rotate through the first bevel gear 12, the rotating rod 14 is further driven to rotate, the gear 15 drives the sealing plate 16 to slide inwards along the inner side wall of the sliding groove 17 through the rotation of the rotating rod 14, after the required materials are added, the feeding pipe 3 is sealed through the sealing plate 16, the quantitative addition of the materials is realized, the further mixing of the materials is realized through the rotation of the blades 8, the mixing efficiency is improved, the quality and the hardness of the produced mold are ensured, the service life of the mold is prolonged, and resources are saved;

the outer side wall of the rotating shaft 9 is fixedly connected with a vibration filtering mechanism in a penetrating mode, the vibration filtering mechanism comprises a special-shaped gear 19 fixedly connected with the outer side wall of the rotating shaft 9 in a penetrating mode, the outer side wall of the special-shaped gear 19 is meshed with a connecting rod 20, teeth are arranged on the outer side wall of the connecting rod 20 and are matched with the teeth arranged on the outer side wall of the special-shaped gear 19, a filter screen 21 is fixedly connected to the bottom of the connecting rod 20, a fixing block 22 is attached to the bottom of the filter screen 21, the outer side wall of the filter screen 21 is connected with the inner side wall of the tank body 1 in a sealing and sliding mode;

will drive the rotation of the special-shaped gear 19 that runs through fixed connection with pivot 9 lateral wall through the rotation of pivot 9, and then make connecting rod 20 drive filter screen 21 upwards slide, when special-shaped gear 19's lateral wall no longer with connecting rod 20's lateral wall intermeshing, filter screen 21 will slide downwards under the action of gravity of self action of gravity and material, make filter screen 21's bottom striking fixed block 22's top, realized the abundant filtration to the material, prevent that the material from filtering the not qualified condition of the abundant mould that leads to, the qualification rate of producing the mould has been guaranteed, thereby the quality of producing the product through the mould has been protected.

When the device is used, materials to be mixed are added through the feeding pipe 3, the blades 8 are driven to rotate under the action of the self gravity of the materials, the rotating shaft 9 is further driven to rotate, the transmission gear 10 is driven to rotate through the rotation of the rotating shaft 9, the transmission rod 11 is further driven to rotate, the transmission rod 11 drives the second bevel gear 13 to rotate through the first bevel gear 12, the rotating rod 14 is further driven to rotate, and the gear 15 drives the sealing plate 16 to slide inwards along the inner side wall of the sliding groove 17 through the rotation of the rotating rod 14;

after the required materials are added, the feeding pipe 3 is sealed by the sealing plate 16, the quantitative addition of the materials is realized, the rotation of the rotating shaft 9 drives the special-shaped gear 19 fixedly connected with the outer side wall of the rotating shaft 9 in a penetrating way, so that the connecting rod 20 drives the filter screen 21 to slide upwards, when the outer side wall of the special-shaped gear 19 is not meshed with the outer side wall of the connecting rod 20, the filter screen 21 slides downwards under the action of self gravity and the gravity of the materials, the bottom of the filter screen 21 impacts the top of the fixing block 22, the materials are fully filtered, after the filtering is finished, the driving motor 24 needs to be started, then the high-temperature vinyl resin is added through the feeding pipe 6, the rotation of the stirring shaft 25 is driven by the rotation of the driving motor 24, so that the stirring sheet 26 rotates, the full mixing of the materials and the high-temperature vinyl resin is realized through the stirring sheet 26, after stirring for one hour, the electromagnetic valve 5 can be opened to collect the materials of the paste through the discharge pipe 4, the operation is simple and rapid, and the use by personnel is convenient.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (8)

1. The utility model provides a pottery experiment mould manufacturing installation, includes a jar body (1), its characterized in that, the bottom fixedly connected with base (2) of the jar body (1), fixedly connected with inlet pipe (3) is run through at the top of the jar body (1), the bottom of the jar body (1) is run through fixedly connected with and is arranged material pipe (4), arrange inside wall fixedly connected with solenoid valve (5) of material pipe (4), the lateral wall of the jar body (1) runs through fixedly connected with filling tube (6), the lateral wall fixedly connected with drive rabbling mechanism of the jar body (1), inside wall top fixed connection dead lever (7) of the jar body (1), the lateral wall through rotation of dead lever (7) is connected with quantitative feeding mechanism.

2. The ceramic experiment mold manufacturing device according to claim 1, wherein the driving stirring mechanism comprises a motor box (23) fixedly connected with the outer side wall of the tank body (1), the inner side wall of the motor box (23) is fixedly connected with a driving motor (24), an output shaft of the driving motor (24) is fixedly connected with a stirring shaft (25), the outer side wall of the stirring shaft (25) is fixedly connected with stirring blades (26), and the end part of the stirring shaft (25) is rotatably connected with the inner side wall of the tank body (1).

3. The ceramic experiment mold manufacturing device according to claim 1, wherein the quantitative feeding mechanism comprises a rotating shaft (9) fixedly connected with the side wall of the fixing rod (7) in a penetrating manner, the outer side wall of the rotating shaft (9) is fixedly connected with blades (8), the outer side wall of the rotating shaft (9) is meshed with a transmission gear (10), the inner side wall of the transmission gear (10) is fixedly connected with a transmission rod (11) in a penetrating manner, the top of the transmission rod (11) is fixedly connected with a first bevel gear (12), the outer side wall of the first bevel gear (12) is meshed with a second bevel gear (13), the inner side wall of the second bevel gear (13) is fixedly connected with a rotating rod (14) in a penetrating manner, the outer side wall of the rotating rod (14) is fixedly connected with a gear (15) in a penetrating manner, and the outer side wall of, the sealed sliding connection of lateral wall of closing plate (16) has spout (17), the lateral wall through rotation of bull stick (14) is connected with connecting block (18), the lateral wall of transfer line (11) is run through to rotate with the top of the jar body (1) and is connected, spout (17) are seted up on the lateral wall of inlet pipe (3), the lateral wall of connecting block (18) and the lateral wall fixed connection of inlet pipe (3), the lateral wall of pivot (9) runs through fixedly connected with vibration filter mechanism.

4. The ceramic experiment mold manufacturing device according to claim 3, wherein the vibration filtering mechanism comprises a special-shaped gear (19) which penetrates through and is fixedly connected with the outer side wall of the rotating shaft (9), the outer side wall of the special-shaped gear (19) is meshed with a connecting rod (20), the bottom of the connecting rod (20) is fixedly connected with a filter screen (21), the bottom of the filter screen (21) is mutually attached with a fixed block (22), the outer side wall of the filter screen (21) is in sealing sliding connection with the inner side wall of the tank body (1), and the outer side wall of the fixed block (22) is fixedly connected with the inner side wall of the tank body (1).

5. The ceramic experimental mold manufacturing device according to claim 1, wherein the feeding pipe (3) is arranged in a square shape, and the feeding pipe (6) is arranged in an L shape.

6. The ceramic experiment mold manufacturing device according to claim 3, wherein the outer side wall of the rotating shaft (9) is provided with threads, and the threads arranged on the outer side wall of the rotating shaft (9) are matched with the threads arranged on the outer side wall of the transmission gear (10).

7. The ceramic experiment mold manufacturing device as claimed in claim 4, wherein the outer side wall of the connecting rod (20) is provided with teeth, and the teeth arranged on the outer side wall of the connecting rod (20) are matched with the teeth arranged on the outer side wall of the special-shaped gear (19).

8. A method for manufacturing a ceramic experimental mold comprises the following steps:

s1: 15-21 parts of high-temperature vinyl resin, 35-49 parts of metallurgical powder black, 27-38 parts of ceramic powder, 8-12 parts of carbon fiber and 15-21 parts of inorganic silicon powder;

s2: sieving the powder with large particles, taking out the powder, and pouring the impurity-free metallurgical powder black, ceramic powder, carbon fiber and inorganic silicon powder into a large container to be fully and uniformly stirred;

s3: adding high-temperature vinyl resin into the powder mixture prepared in the last step, slowly adding the high-temperature vinyl resin while stirring, and fully stirring for one hour to form a paste for later use;

s4: slowly pouring the paste into a prepared model die, immediately heating the model die, keeping the constant temperature for 3 hours after heating to 300 ℃, naturally cooling and die-casting for forming; pressurizing again after one-time die casting molding to ensure that the materials are more compact; heating the mold to 80 ℃ after 2 hours, heating to 150 ℃ again after 3 hours, and keeping the temperature increased by 50 ℃ every hour until the temperature is increased by 300 ℃ and stopping heating; and naturally cooling to obtain the final ceramic die.

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