CN118022576A - Aluminum magnesia carbon brick preparation compounding device - Google Patents

Abstract

The invention relates to the technical field of aluminum magnesia carbon brick production, in particular to an aluminum magnesia carbon brick preparation mixing device, which comprises a shell, wherein a rear seat is fixedly connected to the shell, a screen is rotatably arranged in the shell, a stirring blade is rotatably arranged in the screen, a first ring gear is fixedly connected to the stirring blade, a second ring gear is fixedly connected to the screen, and the device synchronously completes the peeling and screening of fine powder on the surface layer of large particles, does not need to screen the particles after a worker stops working, greatly saves the time required for producing 'original particles', and improves the working efficiency; through the screen cloth rotation, impurity in the screen cloth sieve mesh is cleared up out under the effect of gravity and brush to prevent that the screen cloth from being stopped up, thereby practice thrift the required time of screen cloth clearance, further improve work efficiency.

Description

Aluminum magnesia carbon brick preparation compounding device

Technical Field

The invention relates to the technical field of aluminum magnesia carbon brick production, in particular to a mixing device for aluminum magnesia carbon brick preparation.

Background

Because the aluminum-magnesia carbon brick has good slag resistance and thermal vibration stability, the aluminum-magnesia carbon brick is widely applied to high-temperature strong erosion parts of various furnace linings, water gaps and the like which are in direct contact with molten steel, and the used aluminum-magnesia carbon brick only has a local structure or a local chemical composition which is not changed basically. If the used residual bricks of the aluminum-magnesium-carbon bricks are treated, a large amount of raw materials for producing the aluminum-magnesium-carbon bricks can be obtained, so that national mineral resources can be saved, environmental pollution is reduced, and the cost of refractory materials is reduced.

When the residual bricks of the aluminum-magnesia carbon bricks are treated, the large residual bricks are crushed into large particles by a crusher, the large particles obtained by crushing are mainly false particles formed by wrapping fine powder on the surfaces of the original particles, and the removal of the false particles is a necessary procedure for effectively utilizing the recycled bricks. In the prior art, the common 'pseudo particle' removing mode is to convey large particles into a mixer, and the 'pseudo particles' on the outer layer of the large particles are peeled off by utilizing shearing force, centrifugal force and friction force among the large particles generated in the rotation process of the mixer, but in the prior art, the mixer is equipment for mixing materials and mainly comprises a container and a rotating stirring blade, after the 'pseudo particles' on the outer layer of the large particles are peeled off, the 'pseudo particles' are still mixed with the 'original particles', the required 'original particles' can be obtained after the mixer is stopped and discharged and screened by screening equipment, and a great amount of time is wasted in the process, so that the working efficiency is reduced.

Disclosure of Invention

The invention aims to solve the defect of low efficiency of producing 'primary particles' by a mixer in the prior art, and provides a mixing device for preparing aluminum magnesia carbon bricks.

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

The utility model provides an aluminium magnesia carbon brick preparation compounding device, includes the casing, the rigid coupling has the backseat on the casing, rotatable installs the screen cloth in the casing, rotatable installs stirring vane in the screen cloth, the rigid coupling has first ring gear on the stirring vane, the rigid coupling has second ring gear on the screen cloth, rotatable installs the planet axle on the backseat, the epaxial rigid coupling of planet has planetary gear, first ring gear and second ring gear both match with planetary gear, the rigid coupling has the motor on the backseat, the rigid coupling has the drive wheel in order to drive stirring vane rotation on the output shaft of motor.

Preferably, the back seat is rotatably provided with a reciprocating screw, the reciprocating screw is fixedly connected with a driven wheel, the planetary shaft is fixedly connected with a driving wheel, the driving wheel is matched with the driven wheel, the surface of the screen is slidably matched with a mounting plate, the mounting plate is in threaded connection with the reciprocating screw, and a plurality of cylindrical brushes are connected with the mounting plate through a rotating structure and used for cleaning the screen.

Preferably, the rotating structure comprises two rotating rings rotatably mounted on the mounting plate, and the brush is radially slidably fitted on the rotating rings.

Preferably, the mounting plate is fixedly connected with a collecting box, two sides of the collecting box are fixedly connected with a grate, and the grate is abutted against the rotating ring to clean the hairbrush.

Preferably, the rotating ring is provided with a rotating structure to drive the hairbrush to rotate, the rotating structure comprises a rotating shaft, the rotating shaft is rotatably arranged on the mounting plate, a first end face gear is fixedly connected on the rotating shaft, a plurality of connecting plates are fixedly connected on the rotating ring, an inner spline tube is rotatably arranged on the connecting plates, a gear is fixedly connected on the inner spline tube, the gear is matched with the first end face gear, a spline shaft is slidably matched in the inner spline tube, and the spline shaft is fixedly connected on the hairbrush.

Preferably, the mounting plate is fixedly connected with a second face gear, the rotating ring is rotatably matched with the second face gear, the internal spline tube is fixedly connected with an incomplete gear, and the incomplete gear is matched with the second face gear.

Preferably, the collecting box is fixedly connected with a baffle plate, a guide groove is formed in the baffle plate, a guide block is fixedly connected onto the spline shaft, the guide block is slidably matched in the guide groove, and a compression spring is arranged on the spline shaft to apply elastic force to the guide block.

Preferably, spline grooves are formed in the reciprocating screw, two transmission gears are rotatably arranged on the baffle, the two transmission gears are matched with each other, one transmission gear is matched with the reciprocating screw in a sliding mode, a driving belt wheel is fixedly connected to the transmission gear in a coaxial line mode, a driven belt wheel is fixedly connected to the rotating shaft, and a belt is arranged on the driving belt wheel and the driven belt wheel in a matched mode.

The invention provides a mixing device for preparing aluminum-magnesia carbon bricks, which has the beneficial effects that: the device synchronously finishes the peeling and screening of the fine powder on the surface layer of the large particles, does not need to screen the particles after the working personnel stops, greatly saves the time required for producing the original particles and improves the working efficiency; through the screen cloth rotation, impurity in the screen cloth sieve mesh is cleared up out under the effect of gravity and brush to prevent that the screen cloth from being stopped up, thereby practice thrift the required time of screen cloth clearance, further improve work efficiency.

Drawings

Fig. 1 is a schematic structural diagram of a mixing device for preparing aluminum magnesia carbon bricks.

Fig. 2 is a schematic diagram of the internal structure of a housing of a device for preparing a mixture of aluminum-magnesia carbon bricks according to the present invention.

Fig. 3 is a schematic diagram II of the inside of a shell of the device for preparing and mixing aluminum-magnesia carbon bricks.

Fig. 4 is an enlarged view of a portion a in fig. 3 of a device for preparing a mixture of aluminum-magnesia carbon bricks according to the present invention.

Fig. 5 is a schematic diagram of the structure inside the screen of the device for preparing a mixture from an aluminum magnesia carbon brick.

Fig. 6 is a schematic structural diagram of a mounting plate of a mixing device for preparing aluminum-magnesia carbon bricks.

Fig. 7 is an exploded view of a part of a device for preparing a material mixture for preparing an aluminum-magnesia carbon brick according to the present invention.

Fig. 8 is an enlarged view of B in fig. 7 of a device for preparing and mixing aluminum-magnesia carbon bricks according to the present invention.

Fig. 9 is a front view of fig. 6 of an aluminum magnesia carbon brick preparation mixing device according to the invention.

Fig. 10 is a schematic structural diagram of the inside of a rotating ring of a mixing device for preparing aluminum-magnesia carbon bricks.

Fig. 11 is a schematic structural diagram of a second face gear and an incomplete gear of a mixing device for preparing aluminum-magnesia carbon bricks.

Fig. 12 is a schematic structural diagram of a single face gear and gear cooperation of a mixing device for preparing aluminum-magnesia carbon bricks.

In the figure: 1. a housing; 101. a window; 102. a discharge port; 2. a rear seat; 3. a screen; 4. stirring blades; 5. a motor; 6. a driving wheel; 7. a first ring gear; 8. a second ring gear; 9. a planetary gear; 10. a planetary shaft; 11. a driving wheel; 12. driven wheel; 13. a reciprocating screw; 14. a mounting plate; 15. a baffle; 16. a collection box; 17. a grate; 18. a guide groove; 19. a rotating ring; 20. a rotating shaft; 21. a driven pulley; 22. a first end face gear; 23. a second face gear; 24. a connecting plate; 25. an internally splined tube; 26. an incomplete gear; 27. a spline shaft; 28. a brush; 29. a guide block; 30. a compression spring; 31. a gear; 32. a transmission gear; 33. a driving pulley; 34. a belt.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Example 1

Referring to fig. 1-5, an aluminum magnesia carbon brick preparation mixing device comprises a shell 1, wherein a rear seat 2 is fixedly connected to the shell 1, a screen 3 is rotatably installed in the shell 1, a stirring blade 4 is rotatably installed in the screen 3, a first ring gear 7 is fixedly connected to the stirring blade 4, a second ring gear 8 is fixedly connected to the screen 3, a planetary shaft 10 is rotatably installed on the rear seat 2, a planetary gear 9 is fixedly connected to the planetary shaft 10, the first ring gear 7 and the second ring gear 8 are matched with the planetary gear 9, a motor 5 is fixedly connected to the rear seat 2, and a driving wheel 6 is fixedly connected to an output shaft of the motor 5 to drive the stirring blade 4 to rotate.

The front end of the shell 1 is opened, the tail end of the shell 1 is closed by the rear seat 2, large particles obtained by crushing residual bricks are placed in the front end of the shell 1, under the action of gravity, the large particles are collected at the bottom end inside the screen 3, the motor 5 is restarted, the motor 5 drives the driving wheel 6 to rotate, the driving wheel 6 abuts against the stirring blade 4, the driving wheel 6 rotates to drive the stirring blade 4 to rotate, the stirring blade 4 rotates to stir the large particles, fine powder on the surface of the large particles is peeled off under the action of centrifugal force, shearing force and friction force, the peeled fine powder is discharged from the discharge port 102 at the bottom of the shell 1 through the sieve holes of the screen 3 under the action of gravity, and the screen 3 is the required 'original particles' after screening and is taken out. In the process, the fine powder on the surface layer of the large particles is stripped and screened synchronously, the screening work is not needed after the working personnel stop, the time required for producing the original particles is greatly saved, and the working efficiency is improved.

Because large particles collect in the inside bottom of screen cloth 3 under the action of gravity, therefore, screen cloth 3 also only has the part of bottom can carry out screening work to large particles, in stirring vane 4 rotation in-process, stirring vane 4 can drive first ring gear 7 and rotate, first ring gear 7 drive planetary gear 9 rotates, planetary gear 9 rotates drive second ring gear 8 and rotates, second ring gear 8 rotates and drives screen cloth 3 rotation, screen cloth 3 rotates the part that can make the bottom and rotates to the highest point, at this moment, from the inside impurity to the sieve mesh jam of screen cloth 3, can fall down in the sieve mesh under the action of gravity, thereby prevent the sieve mesh jam of screen cloth 3.

Example 2

As shown in fig. 3-10, a reciprocating screw 13 is rotatably mounted on the rear seat 2, a driven wheel 12 is fixedly connected on the reciprocating screw 13, a driving wheel 11 is fixedly connected on the planetary shaft 10, the driving wheel 11 is matched with the driven wheel 12, a mounting plate 14 is slidably matched with the surface of the screen 3, the mounting plate 14 is in threaded connection with the reciprocating screw 13, and a plurality of cylindrical brushes 28 are connected on the mounting plate 14 through a rotating structure and are used for cleaning the screen 3.

The planetary gear 9 rotates the in-process and drives the planetary shaft 10 to rotate, the planetary shaft 10 rotates and drives the driving wheel 11 to rotate, the driving wheel 11 rotates and drives the driven wheel 12 to rotate, the driven wheel 12 rotates and drives the reciprocating screw 13 to rotate, the mounting plate 14 is driven to do linear reciprocating motion due to the threaded fit of the mounting plate 14 and the reciprocating screw 13, the mounting plate 14 slides axially back and forth at the top of the screen 3 in the linear reciprocating motion process, so that the brush 28 is driven to move back and forth on the screen 3, the brush 28 can extend into the sieve holes of the screen 3 in the moving process, and under the action of friction force and electrostatic force on the surface of the brush, the brush 28 can adsorb impurities attached in the sieve holes of the screen 3, so that the sieve holes of the screen 3 are prevented from being blocked.

As shown in fig. 7-11, the rotating structure comprises two rotating rings 19, the two rotating rings 19 are rotatably arranged on the mounting plate 14, the brushes 28 are radially and slidably matched on the rotating rings 19, the mounting plate 14 is fixedly connected with the collecting box 16, the two sides of the collecting box 16 are fixedly connected with the grate 17, and the grate 17 is abutted against the rotating rings 19 to clean the brushes 28.

The rotating ring 19 is made to rotate, the brush 28 is driven to rotate in the rotating process of the rotating ring 19, the brush head part of the brush 28 stretches out of the outer surface of the rotating ring 19, and as the grate 17 at two sides of the collecting box 16 is propped against the rotating ring 19, the brush head part of the brush 28 can pass through the grate 17 in the rotating process of the rotating ring 19, the grate 17 combs the bristles of the brush 28 and simultaneously the grate 17 can comb down impurities adsorbed on the bristles, so that the cleaning work of the brush 28 is completed, the impurities comb down from the grate 17 fall into the collecting box 16 under the action of gravity, and workers can clean the impurities in the collecting box 16 through the window 101 at the top of the shell 1.

Example 3

As shown in fig. 7-10, spline grooves are formed in the reciprocating screw 13, two transmission gears 32 are rotatably mounted on the baffle 15, the two transmission gears 32 are matched with each other, one transmission gear 32 is slidably matched on the reciprocating screw 13, a driving belt pulley 33 is fixedly connected on a coaxial line on the transmission gear 32, a rotating shaft 20 is rotatably mounted on the mounting plate 14, a driven belt pulley 21 is fixedly connected on the rotating shaft 20, and a belt 34 is mounted on the driving belt pulley 33 and the driven belt pulley 21 in a matched manner.

In the process of rotating the reciprocating screw 13, two transmission gears 32 are further rotated, the transmission gears 32 rotate to drive the driving belt pulley 33 to rotate, and the driving belt pulley 33 rotates to drive the driven belt pulley 21 to rotate through the belt 34, so that the driven belt pulley 21 drives the rotating shaft 20 to rotate.

As shown in fig. 10 and 12, the rotating shaft 20 is fixedly connected with a first end face gear 22, the rotating ring 19 is fixedly connected with a plurality of connecting plates 24, the connecting plates 24 are rotatably provided with an internal spline tube 25, the internal spline tube 25 is fixedly connected with a gear 31, the gear 31 is matched with the first end face gear 22, the internal spline tube 25 is slidably matched with a spline shaft 27, and the spline shaft 27 is fixedly connected with a hairbrush 28.

The rotation in-process of pivot 20 can drive first face gear 22 and rotate, and first face gear 22 rotates and can drive gear 31 and rotate, and gear 31 rotates and drives the rotation of internal spline pipe 25, and the rotation of internal spline pipe 25 drives the rotation of spline shaft 27, and spline shaft 27 rotates and drives brush 28 and rotate, and at the in-process of brush 28 clear up screen cloth 3, impurity brush 28 of rotation state can brush the impurity in the sieve mesh to improve the clearance quality.

As shown in fig. 7-11, the mounting plate 14 is fixedly connected with a second face gear 23, the rotating ring 19 is rotatably matched with the second face gear 23, the internal spline tube 25 is fixedly connected with an incomplete gear 26, the incomplete gear 26 is matched with the second face gear 23, the collecting box 16 is fixedly connected with a baffle plate 15, the baffle plate 15 is provided with a guide groove 18, the spline shaft 27 is fixedly connected with a guide block 29, the guide block 29 is slidably matched in the guide groove 18, and the spline shaft 27 is provided with a compression spring 30 to apply elastic force to the guide block 29.

The incomplete gear 26 is driven to rotate during the rotation of the internally splined tube 25, and because the incomplete gear 26 is matched with the second face gear 23 and the second face gear 23 is in a fixed state, when the incomplete gear 26 is meshed with the second face gear 23, the incomplete gear 26 revolves around the second face gear 23, and the revolution of the incomplete gear 26 drives the rotating ring 19 to rotate.

In the process of rotating the rotating ring 19, the rotating ring 19 drives the guide block 29 to slide in the guide groove 18, as shown in fig. 7, the whole guide groove 18 is round with a gap in part, when the guide block 29 slides in the guide groove 18, the guide block 29 can radially move along the rotating ring 19 under the elastic force of the compression spring 30 when the guide block 29 moves to the gap, the guide block 29 drives the brush 28 to radially move along the rotating ring 19, and the brush 28 radially impacts the sieve holes of the screen 3 in the moving process, so that impurities attached in the sieve holes are flushed down, and the cleaning quality of the brush 28 on the screen 3 is improved.

Working principle and working procedure:

The front end of the shell 1 is opened, the tail end of the shell 1 is closed by the rear seat 2, large particles obtained by crushing residual bricks are placed in the front end of the shell 1, under the action of gravity, the large particles are collected at the bottom end inside the screen 3, the motor 5 is restarted, the motor 5 drives the driving wheel 6 to rotate, the driving wheel 6 abuts against the stirring blade 4, the driving wheel 6 rotates to drive the stirring blade 4 to rotate, the stirring blade 4 rotates to stir the large particles, fine powder on the surface of the large particles is peeled off under the action of centrifugal force, shearing force and friction force, the peeled fine powder is discharged from the discharge port 102 at the bottom of the shell 1 through the sieve holes of the screen 3 under the action of gravity, and the screen 3 is the required 'original particles' after screening and is taken out. In the process, the fine powder on the surface layer of the large particles is stripped and screened synchronously, the screening work is not needed after the working personnel stop, the time required for producing the original particles is greatly saved, and the working efficiency is improved.

Because large particles collect in the inside bottom of screen cloth 3 under the action of gravity, therefore, screen cloth 3 also only has the part of bottom can carry out screening work to large particles, in stirring vane 4 rotation in-process, stirring vane 4 can drive first ring gear 7 and rotate, first ring gear 7 drive planetary gear 9 rotates, planetary gear 9 rotates drive second ring gear 8 and rotates, second ring gear 8 rotates and drives screen cloth 3 rotation, screen cloth 3 rotates the part that can make the bottom and rotates to the highest point, at this moment, from the inside impurity to the sieve mesh jam of screen cloth 3, can fall down in the sieve mesh under the action of gravity, thereby prevent the sieve mesh jam of screen cloth 3.

The planetary gear 9 rotates the in-process and drives the planetary shaft 10 to rotate, the planetary shaft 10 rotates and drives the driving wheel 11 to rotate, the driving wheel 11 rotates and drives the driven wheel 12 to rotate, the driven wheel 12 rotates and drives the reciprocating screw 13 to rotate, the mounting plate 14 is driven to do linear reciprocating motion due to the threaded fit of the mounting plate 14 and the reciprocating screw 13, the mounting plate 14 slides axially back and forth at the top of the screen 3 in the linear reciprocating motion process, so that the brush 28 is driven to move back and forth on the screen 3, the brush 28 can extend into the sieve holes of the screen 3 in the moving process, and under the action of friction force and electrostatic force on the surface of the brush, the brush 28 can adsorb impurities attached in the sieve holes of the screen 3, so that the sieve holes of the screen 3 are prevented from being blocked.

The reciprocating screw 13 rotates the in-process and still can make two drive gears 32 rotate, drive gear 32 rotates and drives driving pulley 33 to rotate, driving pulley 33 rotates and drives driven pulley 21 through belt 34 and rotate, thereby make driven pulley 21 drive pivot 20 rotate, the pivot 20 rotates the in-process and can drive first terminal surface gear 22 and rotate, first terminal surface gear 22 rotates and can drive gear 31 and rotate, gear 31 rotates and drives internal spline pipe 25 and rotate, internal spline pipe 25 rotates and drives the integral key shaft 27 and rotate, integral key shaft 27 rotates and drives the brush 28 to rotate, in the in-process that the brush 28 clear up screen cloth 3, impurity brush 28 in the sieve mesh can be brushed down to the rotation state, thereby improve the clearance quality.

The incomplete gear 26 is driven to rotate in the rotation process of the internal spline tube 25, because the incomplete gear 26 is matched with the second face gear 23 and the second face gear 23 is in a fixed state, when the incomplete gear 26 is meshed with the second face gear 23, the incomplete gear 26 revolves around the second face gear 23, the incomplete gear 26 revolves to drive the rotating ring 19 to rotate, the brush 28 is driven to rotate in the rotation process of the rotating ring 19, the brush head part of the brush 28 stretches out of the outer surface of the rotating ring 19, and because the comb 17 at two sides of the collecting box 16 is abutted against the rotating ring 19, in the rotation process of the rotating ring 19, the brush head part of the brush 28 passes through the comb 17 in the rotation process, the comb 17 combs the bristles of the brush 28, and simultaneously, the impurities adsorbed on the bristles are combed down, so that the cleaning work of the brush 28 is completed, the impurities combed down by the comb 17 fall into the collecting box 16 under the action of gravity, and the impurities in the collecting box 16 can be cleaned by workers through the window 101 at the top of the shell 1.

In the process of rotating the rotating ring 19, the rotating ring 19 drives the guide block 29 to slide in the guide groove 18, as shown in fig. 7, the whole guide groove 18 is round with a gap in part, when the guide block 29 slides in the guide groove 18, the guide block 29 can radially move along the rotating ring 19 under the elastic force of the compression spring 30 when the guide block 29 moves to the gap, the guide block 29 drives the brush 28 to radially move along the rotating ring 19, and the brush 28 radially impacts the sieve holes of the screen 3 in the moving process, so that impurities attached in the sieve holes are flushed down, and the cleaning quality of the brush 28 on the screen 3 is improved.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (8)

1. The utility model provides an aluminium magnesia carbon brick preparation compounding device, its characterized in that, including casing (1), the rigid coupling has backseat (2) on casing (1), rotatable screen cloth (3) are installed in casing (1), rotatable stirring vane (4) are installed in screen cloth (3), the rigid coupling has first ring gear (7) on stirring vane (4), the rigid coupling has second ring gear (8) on screen cloth (3), rotatable installation planetary shaft (10) on backseat (2), rigid coupling has planetary gear (9) on planetary shaft (10), both with planetary gear (9) phase-match in first ring gear (7) and second ring gear (8), rigid coupling has motor (5) on backseat (2), the rigid coupling has drive wheel (6) in order to drive stirring vane (4) rotation on the output shaft of motor (5).

2. The aluminum magnesia carbon brick preparation mixing device according to claim 1, wherein a reciprocating screw (13) is rotatably installed on the rear seat (2), a driven wheel (12) is fixedly connected on the reciprocating screw (13), a driving wheel (11) is fixedly connected on the planetary shaft (10), the driving wheel (11) is matched with the driven wheel (12), a mounting plate (14) is slidably matched with the surface of the screen (3), the mounting plate (14) is in threaded connection with the reciprocating screw (13), and a plurality of cylindrical brushes (28) are connected on the mounting plate (14) through a rotating structure to clean the screen (3).

3. An aluminium magnesia carbon brick preparation mixing device according to claim 2, characterized in that the rotating structure comprises two rotating rings (19), the two rotating rings (19) are rotatably mounted on the mounting plate (14), and the brushes (28) are radially slidably fitted on the rotating rings (19).

4. An aluminium magnesia carbon brick preparation mixing device according to claim 3, characterized in that the mounting plate (14) is fixedly connected with a collecting box (16), two sides of the collecting box (16) are fixedly connected with a grate (17), and the grate (17) is abutted against the rotating ring (19) to clean the brush (28).

5. The alumina magnesia carbon brick preparation compounding device of claim 4, wherein the rotating ring (19) is provided with a rotating structure to drive the hairbrush (28) to rotate, the rotating structure comprises a rotating shaft (20), the rotating shaft (20) is rotatably arranged on the mounting plate (14), a first end face gear (22) is fixedly connected on the rotating shaft (20), a plurality of connecting plates (24) are fixedly connected on the rotating ring (19), an inner spline tube (25) is rotatably arranged on the connecting plates (24), a gear (31) is fixedly connected on the inner spline tube (25), the gear (31) is matched with the first end face gear (22), a spline shaft (27) is slidably matched in the inner spline tube (25), and the spline shaft (27) is fixedly connected on the hairbrush (28).

6. The aluminum magnesia carbon brick preparation mixing device according to claim 5, wherein the mounting plate (14) is fixedly connected with a second face gear (23), the rotating ring (19) is rotatably matched with the second face gear (23), the internal spline tube (25) is fixedly connected with an incomplete gear (26), and the incomplete gear (26) is matched with the second face gear (23).

7. The aluminum magnesia carbon brick preparation mixing device according to claim 6, wherein the collecting box (16) is fixedly connected with a baffle plate (15), the baffle plate (15) is provided with a guide groove (18), the spline shaft (27) is fixedly connected with a guide block (29), the guide block (29) is slidably matched in the guide groove (18), and the spline shaft (27) is provided with a compression spring (30) to apply elasticity to the guide block (29).

8. The aluminum magnesia carbon brick preparation mixing device according to claim 7, wherein spline grooves are formed in the reciprocating screw (13), two transmission gears (32) are rotatably arranged on the baffle (15), the two transmission gears (32) are matched with each other, one transmission gear (32) is slidably matched with the reciprocating screw (13), a driving belt wheel (33) is fixedly connected on a coaxial line on the transmission gear (32), a driven belt wheel (21) is fixedly connected on the rotating shaft (20), and a belt (34) is matched and arranged on the driving belt wheel (33) and the driven belt wheel (21).