CN111514989B - High strength ceramic manufacture that can effectively dredge uses raw material processing apparatus - Google Patents

Abstract

The invention discloses a raw material processing device for high-strength ceramic production, which can be effectively dredged and comprises an outer shell, wherein the lower end of the outer shell is connected with supporting legs, the upper end of the outer shell is provided with a servo motor, the shaft end of the servo motor is connected with the left shaft end of a grinding cylinder through a belt transmission structure, the grinding cylinder is arranged in the outer shell, the left shaft end and the right shaft end of the grinding cylinder are both provided with bearings which penetrate through the outer shell, a deflector rod is fixedly connected to the part of the left shaft end of the grinding cylinder, which is positioned in the outer shell, filtering holes are distributed in the grinding cylinder, grinding balls are contained in the grinding cylinder, and the right side surface of the outer shell is connected with a baffle cover in a shaft mode. This raw materials processing apparatus for high strength ceramic manufacture that can effectively dredge can effectual mediation by the filtration pore that ceramic raw materials blockked up to can be convenient for improve the device to ceramic raw materials's processing, and can reduce staff's intensity of labour.

Description

High strength ceramic manufacture that can effectively dredge uses raw material processing apparatus

Technical Field

The invention relates to the technical field of ceramic production, in particular to a raw material processing device for high-strength ceramic production, which can be effectively dredged.

Background

The ceramic is a container or artwork manufactured by manufacturing a mud blank from a ceramic raw material and then sintering, and since the ceramic is invented by China at first and the ceramic in China is reputed to be inside and outside the world, the English of the ceramic is also china, and the influence of the ceramic in China on the world is reflected;

but current raw materials processing apparatus for ceramic manufacture is when using, is blockked up by ceramic raw materials easily, this is because when current to ceramic raw materials handles, grinding ball cooperation grinding vessel can ceramic raw materials pulverize, but also can extrude the ceramic raw materials of great piece to the filtration pore in, and then make the filtration pore blockked up, thereby be not convenient for improve the efficiency that the device handled ceramic raw materials, and when current mode dredged processing apparatus, what generally adopted is that artificial mode dredges, and not only inefficiency, and can increase staff's work burden.

To sum up, a raw material processing device for high-strength ceramic production, which can be effectively dredged, is designed to solve the above problems.

Disclosure of Invention

The invention aims to provide a raw material processing device for high-strength ceramic production, which can be effectively dredged, and solves the problem that the existing raw material processing device for ceramic production can not effectively dredge filter holes blocked by ceramic raw materials in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a raw material processing device for high-strength ceramic production capable of being effectively dredged comprises an outer shell, wherein the lower end of the outer shell is connected with supporting legs, the upper end of the outer shell is provided with a servo motor, the shaft end of the servo motor is connected with the left shaft end of a grinding cylinder through a belt transmission structure, the grinding cylinder is arranged in the outer shell, the left shaft end and the right shaft end of the grinding cylinder both penetrate through the outer shell in a bearing mode, a deflector rod is fixedly connected to the part, located in the outer shell, of the left shaft end of the grinding cylinder, filtering holes are distributed in the grinding cylinder, grinding balls are contained in the grinding cylinder, a baffle cover is connected to the right side face of the outer shell in a shaft mode, a self-resetting inner toothed ring is fixedly connected to the inner top end of the outer shell, a squeezing plate is arranged on the lower surface of the bearing, a self-resetting inner toothed ring is connected to the left side face of the inner side face of the outer shell, and a linkage rod is fixedly connected to the inner side face part, close to the inner side face of the outer shell, the left side and the right side of the inner part of the outer shell are both provided with chutes, the chutes are internally and slidably connected with sliders, block sleeves are nested on the outer sides of the sliders and fixedly connected to the left end and the right end of the mounting plate, the mounting plate is arranged between the grinding cylinder and the bearing plate, connecting cavities are reserved at the left end and the right end of the middle part of the lower surface of the mounting plate, the upper ends of connecting rods extend into the connecting cavities, the outer sides of the upper ends of the connecting rods and the inner sides of the connecting cavities are respectively welded and fixed at the two ends of a second compression spring, the lower ends of the connecting rods are fixedly connected with self-resetting shaft levers, the self-resetting shaft levers are connected to the inner side of the outer shell through bearings, electric telescopic dredging rods movably penetrate through the mounting plate, the middle lower parts of the electric telescopic dredging rods are connected with the lower surface of the mounting plate through telescopic hoses, and the upper ends of the electric telescopic dredging rods are fixedly connected to the lower surface of the bearing strip-shaped plate, and the lower surface of the pressure-bearing strip-shaped plate and the upper surface of the mounting plate are respectively welded and fixed at two ends of the first compression spring, and teeth are distributed at two ends of the upper surface of the pressure-bearing strip-shaped plate.

Preferably, the right shaft end of the grinding cylinder penetrates through the inside of the grinding cylinder and the outside, and the distance between the right shaft end of the grinding cylinder and the lower end of the blocking cover ranges from 0.1 cm to 0.5 cm.

Preferably, the axis of the self-resetting internal tooth ring is collinear with the axis of the grinding cylinder, and teeth matched with the teeth on the pressure bearing strip-shaped plate are distributed on the inner side surface of the self-resetting internal tooth ring.

Preferably, the connection mode of the block sleeve and the sliding block is the same as that of the mounting plate and the connecting rod, and the connecting rod is perpendicular to the self-resetting shaft rod.

Preferably, the mounting panel is the arc, and the mounting panel seamlessly splices in flexible hose's both ends respectively with electronic flexible dredging rod.

Preferably, the pressure-bearing strip-shaped plate is arc-shaped, and electric telescopic dredging rods are distributed on the lower surface of the pressure-bearing strip-shaped plate at equal intervals.

Preferably, one side of the extrusion plate facing the grinding cylinder is a curved surface, and the distance between the curved surface and the axis of the grinding cylinder is gradually reduced.

Preferably, the deflector rod is L-shaped, and the distance between the deflector rod and the axis of the left shaft end of the grinding cylinder is smaller than the minimum distance between the axis of the left shaft end of the grinding cylinder and the lower surface of the pressure-bearing strip-shaped plate.

Preferably, the positions of the electric telescopic dredging rods and the positions of the filter holes are arranged in a one-to-one correspondence mode, the number of rows of the filter holes is equal to that of the rows of the electric telescopic dredging rods, and the filter holes are only distributed on the 1/6 circumference of the outer side of the grinding cylinder.

Preferably, the sliding chute is of a 'return' structure formed by two sections of arcs, the arc center of the sliding chute is located on the axis of the self-resetting shaft rod, the depth of the arc rear end of the upper position and the lower position of the sliding chute is greater than the depth of the arc of the upper position of the sliding chute, meanwhile, the depth of the arc front end of the lower position is equal to the depth of the arc of the upper position of the sliding chute, and the inner bottom surface of the arc of the upper position and the lower position of the sliding chute is of a curved surface structure.

Compared with the prior art, the invention has the beneficial effects that: this raw materials processing apparatus for high strength ceramic manufacture that can effectively dredge can effectual mediation be by the filtration pore that ceramic raw materials blockked up to can be convenient for improve the device to ceramic raw materials's processing, and can reduce staff's intensity of labour:

1. the driving lever and the linkage rod drive the self-reset inner toothed ring to intermittently rotate, the pressure-bearing strip-shaped plate can be driven to intermittently rotate, and after the pressure-bearing strip-shaped plate rotates once, the pressure-bearing strip-shaped plate can be extruded by the extrusion block, so that the electric telescopic dredging rod extends into the filter hole, the filter hole is dredged, and after the electric telescopic dredging rod extends into the filter hole, the pressure-bearing strip-shaped plate can be reset through the reverse sliding of the sliding block in the sliding groove, so that the filter hole is dredged again;

2. the filter holes are dredged when the grinding cylinder rotates, the condition that the filter holes are dredged manually by stopping the machine in the past can be avoided, the labor intensity of workers is reduced, and the efficiency of the device for treating ceramic raw materials is improved.

Drawings

FIG. 1 is a schematic main sectional view of the present invention;

FIG. 2 is an enlarged view of point A of FIG. 1 according to the present invention;

FIG. 3 is a schematic side sectional view of the polishing drum of the present invention;

FIG. 4 is a schematic view of the connection structure of the grinding cylinder and the self-resetting internal gear ring of the invention;

FIG. 5 is a schematic view of the connection structure of the mounting plate and the pressure-bearing strip-shaped plate according to the present invention;

FIG. 6 is a schematic view of the connecting rod and mounting plate connection structure of the present invention;

FIG. 7 is a schematic view of a slider and runner connection structure of the present invention;

FIG. 8 is a side sectional view of the chute of the present invention.

In the figure: 1. an outer housing; 2. supporting legs; 3. a servo motor; 4. a belt drive structure; 5. a grinding cylinder; 6. filtering holes; 7. a blocking cover; 8. a pressure bearing plate; 9. a self-resetting internal gear ring; 10. a block sleeve; 11. mounting a plate; 12. a pressure-bearing strip plate; 13. grinding balls; 14. a pressing plate; 15. a deflector rod; 16. a linkage rod; 17. teeth; 18. an electric telescopic dredging rod; 19. a flexible hose; 20. a first compression spring; 21. a connecting rod; 22. a self-resetting shaft lever; 23. a slider; 24. a chute; 25. a connecting cavity; 26. a second compression spring.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a raw material processing device for high-strength ceramic production capable of being effectively dredged comprises an outer shell 1, supporting legs 2, a servo motor 3, a belt transmission structure 4, a grinding cylinder 5, a filter hole 6, a baffle cover 7, a bearing plate 8, a self-resetting inner toothed ring 9, a block sleeve 10, a mounting plate 11, a bearing strip-shaped plate 12, grinding balls 13, an extrusion plate 14, a deflector rod 15, a linkage rod 16, teeth 17, an electric telescopic dredging rod 18, a telescopic hose 19, a first compression spring 20, a connecting rod 21, a self-resetting shaft rod 22, a sliding block 23, a sliding chute 24, a connecting cavity 25 and a second compression spring 26, wherein the supporting legs 2 are connected to the lower end of the outer shell 1, the servo motor 3 is mounted at the upper end of the outer shell 1, the shaft end of the servo motor 3 is connected with the left shaft end of the grinding cylinder 5 through the belt transmission structure 4, the grinding cylinder 5 is arranged inside the outer shell 1, bearings on the left side and the right side of the grinding cylinder 5 penetrate through the outer shell 1, and the left shaft end of the grinding cylinder 5 is fixedly connected with a deflector rod 15 on the part inside the outer shell 1, the grinding cylinder 5 is distributed with filter holes 6, the grinding cylinder 5 is internally provided with grinding balls 13, the right side surface of the outer shell 1 is connected with a baffle cover 7 in a shaft way, the inner top end of the outer shell 1 is fixedly connected with a bearing plate 8, the lower surface of the bearing plate 8 is provided with a squeezing plate 14, the left side surface of the inner part of the outer shell 1 is connected with a self-resetting inner toothed ring 9 in a bearing way, the inner side part of the self-resetting inner toothed ring 9 close to the inner side surface of the outer shell 1 is fixedly connected with a linkage rod 16, the left side and the right side of the inner part of the outer shell 1 are both provided with sliding chutes 24, the sliding chutes 24 are internally connected with sliding blocks 23 in the sliding ways, the outer sides of the sliding blocks 23 are nested with block sleeves 10, the block sleeves 10 are fixedly connected with the left end and the right end of the mounting plate 11, the mounting plate 11 is arranged between the grinding cylinder 5 and the bearing plate 8, and the left end and right end of the middle part of the lower surface of the mounting plate 11 are both reserved with connecting cavities 25, the upper end that has connecting rod 21 stretches into in connecting chamber 25, and the upper end outside of connecting rod 21 and the inboard of connecting chamber 25 welded fastening respectively in the both ends of second compression spring 26, the lower extreme fixedly connected with of connecting rod 21 is from restoring to the throne axostylus axostyle 22, and from restoring to the throne axostylus axostyle 22 bearing connection in the inboard of shell body 1, the activity runs through on the mounting panel 11 has electronic flexible dredging rod 18, and the well lower part of electronic flexible dredging rod 18 is connected through bellows 19 with the lower surface of mounting panel 11, the upper end fixed connection of electronic flexible dredging rod 18 is in the lower surface of pressure-bearing strip shaped plate 12, and the lower surface of pressure-bearing strip shaped plate 12 and the upper surface of mounting panel 11 welded fastening respectively in the both ends of first compression spring 20, and the both ends of pressure-bearing strip shaped plate 12 upper surface are equallyd divide cloth and are had tooth 17.

The right shaft end of the grinding cylinder 5 penetrates through the inside and the outside of the grinding cylinder 5, the distance range between the right shaft end of the grinding cylinder 5 and the lower end of the blocking cover 7 is 0.1-0.5cm, ceramic raw materials can be conveniently added into the grinding cylinder 5 through the right shaft end of the grinding cylinder 5, and the splashing of the ceramic raw materials when the device is used for treating the ceramic raw materials can be reduced through the blocking cover 7.

The axis of the self-resetting inner gear ring 9 is collinear with the axis of the grinding cylinder 5, and the teeth 17 matched with the teeth 17 on the pressure-bearing strip-shaped plate 12 are distributed on the inner side surface of the self-resetting inner gear ring 9, so that the grinding cylinder 5 can rotate conveniently, and the self-resetting inner gear ring 9 is stably driven to rotate.

The block sleeve 10 and the sliding block 23 are connected in the same way as the mounting plate 11 and the connecting rod 21, and the connecting rod 21 is perpendicular to the self-resetting shaft rod 22, so that the sliding block 23 can slide in the sliding groove 24 at different depths.

The mounting panel 11 is the arc, and seamless splicing in the both ends of bellows 19 respectively of mounting panel 11 and electronic flexible dredging rod 18 can reduce the device through bellows 19 when handling ceramic raw materials, and ceramic raw materials powder gets into the position that mounting panel 11 and electronic flexible dredging rod 18 are connected to can be convenient for guarantee that electronic flexible dredging rod 18 is stable to move about on mounting panel 11.

The pressure-bearing strip-shaped plate 12 is the arc, and the equidistant distribution of lower surface of pressure-bearing strip-shaped plate 12 has electronic flexible dredging rod 18, the position of electronic flexible dredging rod 18 sets up with the position one-to-one of straining hole 6, and strain 6 row's of hole number and electronic flexible dredging rod 18's row's number equal, and strain hole 6 only distributes on the 1/6 circumference in the grinding vessel 5 outside, when the pressure-bearing strip-shaped plate 12 of can being convenient for drives electronic flexible dredging rod 18 and moves down, make the straining hole 6 of a plurality of rows of numbers link up simultaneously, avoided straining hole 6 to be blockked up by ceramic raw materials.

The side of the pressing plate 14 facing the grinding cylinder 5 is a curved surface, and the distance from the curved surface to the axis of the grinding cylinder 5 gradually decreases, so that when the pressure-bearing strip-shaped plate 12 rotates relative to the pressing plate 14, the pressure-bearing strip-shaped plate 12 is gradually pressed, and the pressure-bearing strip-shaped plate 12 gradually approaches the grinding cylinder 5.

The deflector rod 15 is L-shaped, and the distance between the deflector rod 15 and the axis of the left shaft end of the grinding cylinder 5 is smaller than the minimum distance between the axis of the left shaft end of the grinding cylinder 5 and the lower surface of the pressure-bearing strip-shaped plate 12, so that the deflector rod 15 can conveniently deflect the linkage rod 16, and the deflector rod 15 can be prevented from blocking the movement of the pressure-bearing strip-shaped plate 12.

The sliding groove 24 is a structure shaped like a Chinese character 'hui' formed by two sections of arcs, the arc center of the sliding groove 24 is located on the axis of the self-reset shaft lever 22, the depth of the arc rear end of the upper position and the lower position of the sliding groove 24 is larger than that of the arc above the sliding groove, meanwhile, the depth of the arc front end of the lower position is equal to that of the arc above the sliding groove, the arc inner bottom surface of the upper position and the lower position of the sliding groove 24 is of a curved surface structure, when the sliding block 23 slides to the arc rear end of the upper position of the sliding groove 24, the sliding block moves to the arc rear end of the lower position of the sliding groove 24 under the action of the first compression spring 20, and then the mounting plate 11 is reset through resetting of the self-reset shaft lever 22, so that the sliding block 23 slides to the front end from the arc rear end of the lower position of the sliding groove 24 and moves to the arc front end of the upper position under the action of the arc and the second compression spring 26 of the curved surface structure.

The working principle is as follows: the raw material processing device for the high-strength ceramic production, which can be effectively dredged, is firstly installed at a use position, and is switched on, and then is operated and used through the following operation modes:

according to fig. 1-8, the shield cover 7 is rotated and ceramic raw material is poured into the interior of the grinding vessel 5 through the right shaft end of the grinding vessel 5;

then, the servo motor 3 is started, so that the servo motor 3 drives the grinding cylinder 5 to rotate through the belt transmission structure 4, and the grinding balls 13 in the grinding cylinder 5 grind the ceramic raw materials;

when the ground ceramic raw material is smaller than the filter holes 6, the ground ceramic raw material is discharged out of the grinding cylinder 5 through the filter holes 6, and when the ground ceramic raw material is larger than the filter holes 6, the ground ceramic raw material continues to be ground by the grinding balls 13 in the grinding cylinder 5;

in the process of processing the ceramic raw materials, a part of ceramic raw materials with larger volume can be smashed into the filter holes 6 due to the action of the grinding balls 13, so that the filter holes 6 are blocked;

therefore, when the grinding cylinder 5 rotates, the driving lever 15 is driven to rotate, and the self-resetting inner gear ring 9 is driven to rotate by the driving linkage rod 16;

when the self-resetting inner toothed ring 9 rotates, the pressure-bearing strip-shaped plate 12 is driven to rotate through the teeth 17 until the pressure-bearing strip-shaped plate 12 is gradually extruded by the extrusion plate 14 until the pressure-bearing strip-shaped plate 12 is separated from the teeth 17 on the self-resetting inner toothed ring 9;

in the process that the pressure-bearing strip-shaped plate 12 is extruded by the extrusion plate 14, the pressure-bearing strip-shaped plate 12 drives the electric telescopic dredging rod 18 to synchronously move, and when the filtering holes 6 on the grinding cylinder 5 rotate to the positions of the electric telescopic dredging rod 18, the electric telescopic dredging rod 18 just extends into the filtering holes 6, so that the filtering holes 6 are dredged;

after the electric telescopic dredging rod 18 extends into the filtering hole 6, the pressure-bearing strip-shaped plate 12 is separated from the teeth 17 on the self-resetting inner toothed ring 9, and then after the electric telescopic dredging rod 18 rotates synchronously with the grinding cylinder 5 for a certain angle, during the synchronous rotation of the electric dredging bar 18 with the grinding cylinder 5, the electric dredging bar 18 is started and shortened until the two are separated, and thereafter, the slider 23 will also slide to the rear end of the upper arc of the chute 24, after which, by the action of the first compression spring 20, the slider 23 is made to slide into the lower arc of the chute 24, and under the reset action force of the self-reset shaft lever 22, the slide block 23 slides in the lower arc of the slide groove 24 to the front end, and under the action of the second compression spring 26, the slide block 23 slides from the lower arc-shaped front end of the slide groove 24 to the upper arc-shaped front end, thereby resetting the electrically telescoping dredge pole 18, and then starting the electrically telescoping dredge pole 18 to extend to the initial length;

the above process is repeated to automatically dredge the filter holes 6 and avoid the blockage thereof in the process of processing the ceramic raw material by the device, and the details which are not described in detail in the specification belong to the prior art which is well known to the professional in the field.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. The utility model provides a raw material processing apparatus for high strength ceramic manufacture that can effectively dredge, includes shell body (1), its characterized in that: the grinding machine is characterized in that the lower end of the outer shell (1) is connected with a supporting leg (2), a servo motor (3) is installed at the upper end of the outer shell (1), the shaft end of the servo motor (3) is connected with the left shaft end of a grinding cylinder (5) through a belt transmission structure (4), the grinding cylinder (5) is arranged inside the outer shell (1), bearings of the left shaft end and the right shaft end of the grinding cylinder (5) penetrate through the outer shell (1) and are fixedly connected with a deflector rod (15) on the part of the left shaft end of the grinding cylinder (5) inside the outer shell (1), filtering holes (6) are distributed in the grinding cylinder (5), grinding balls (13) are contained in the grinding cylinder (5), the right side face of the outer shell (1) is connected with a blocking cover (7) in a shaft mode, a bearing plate (8) is fixedly connected with the inner top end of the outer shell (1), and an extrusion plate (14) is arranged on the lower surface of the bearing plate (8), the left side bearing inside the outer shell (1) is connected with a self-resetting inner toothed ring (9), the inner side of the self-resetting inner toothed ring (9) is close to the inner side surface part of the outer shell (1) and is fixedly connected with a linkage rod (16), the left side and the right side inside the outer shell (1) are both provided with sliding chutes (24), the sliding chutes (24) are internally and slidably connected with sliding blocks (23), the outer sides of the sliding blocks (23) are nested with block sleeves (10), the block sleeves (10) are fixedly connected with the left end and the right end of a mounting plate (11), the mounting plate (11) is arranged between a grinding cylinder (5) and a bearing plate (8), connecting cavities (25) are reserved at the left end and the right end of the middle part of the lower surface of the mounting plate (11), the upper ends of connecting rods (21) are stretched into the connecting cavities (25), and the outer sides of the upper ends of the connecting rods (21) and the inner sides of the connecting cavities (25) are respectively welded and fixed at the two ends of a second compression spring (26), the lower end of the connecting rod (21) is fixedly connected with a self-resetting shaft lever (22), the self-resetting shaft lever (22) is connected to the inner side of the outer shell (1) in a bearing mode, an electric telescopic dredging rod (18) penetrates through the mounting plate (11) in a movable mode, the middle lower portion of the electric telescopic dredging rod (18) is connected with the lower surface of the mounting plate (11) through a telescopic hose (19), the upper end of the electric telescopic dredging rod (18) is fixedly connected to the lower surface of the pressure-bearing strip-shaped plate (12), the lower surface of the pressure-bearing strip-shaped plate (12) and the upper surface of the mounting plate (11) are fixedly welded to the two ends of the first compression spring (20) respectively, and teeth (17) are distributed at the two ends of the upper surface of the pressure-bearing strip-shaped plate (12);

the axis of ring gear (9) and the axis collineation of grinding vessel (5) in restoring to throne, and the medial surface of ring gear (9) distributes and go up anastomotic tooth (17) of tooth (17) with pressure-bearing strip shaped plate (12) from the restoring to throne, mounting panel (11) are the arc, and mounting panel (11) and electronic flexible dredging rod (18) seamless joint in the both ends of bellows (19) respectively, pressure-bearing strip shaped plate (12) are the arc, and the equidistant distribution of lower surface of pressure-bearing strip shaped plate (12) has electronic flexible dredging rod (18), the position of electronic flexible dredging rod (18) sets up with the position one-to-one of filtration pore (6), and filtration pore (6) row number equals with the row number of electronic flexible dredging rod (18) to filtration pore (6) only distribute on the 1/6 circumference in the grinding vessel (5) outside.

2. The raw material processing device for high-strength ceramic production, which can be dredged effectively according to claim 1, is characterized in that: the right shaft end of the grinding cylinder (5) penetrates through the inside and the outside of the grinding cylinder (5), and the distance between the right shaft end of the grinding cylinder (5) and the lower end of the baffle cover (7) ranges from 0.1 cm to 0.5 cm.

3. The raw material processing device for high-strength ceramic production, which can be dredged effectively according to claim 1, is characterized in that: one side of the extrusion plate (14) facing the grinding cylinder (5) is a curved surface, and the distance between the curved surface and the axis of the grinding cylinder (5) is gradually reduced.

4. The raw material processing device for high-strength ceramic production, which can be dredged effectively according to claim 1, is characterized in that: the shifting rod (15) is L-shaped, and the distance between the shifting rod (15) and the axis of the left shaft end of the grinding cylinder (5) is smaller than the minimum distance between the axis of the left shaft end of the grinding cylinder (5) and the lower surface of the pressure-bearing strip-shaped plate (12).

5. The raw material processing device for high-strength ceramic production, which can be dredged effectively according to claim 1, is characterized in that: the sliding groove (24) is of a 'return' structure formed by two sections of arcs, the arc center of the sliding groove (24) is located on the axis of the self-resetting shaft lever (22), and the inner bottom surfaces of the arcs at the upper and lower positions of the sliding groove (24) are of curved surface structures.

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