CN220178911U - Ball forming machine for molecular sieve preparation - Google Patents

Abstract

The utility model relates to the technical field of balling devices, and discloses a balling machine for molecular sieve preparation, which comprises an equipment box, wherein a feed inlet is fixedly arranged at the top end of the equipment box, a driving box is arranged on the front end wall surface of the equipment box, a motor is fixedly arranged on the outer wall surface of the driving box, a discharge pipe is arranged at the rear of the equipment box, a balling component is arranged in a cavity of the equipment box, the balling component comprises a rotating roller, a forming component is arranged below the rotating roller, and the forming component comprises a polishing pipe. The spherical molecular sieve powder is prepared into the spherical shape through setting up the ball forming assembly, through setting up the shaping assembly in the below of ball forming assembly, the pipe of polishing constantly rotates can polish spherical molecular sieve for the surface is smooth, can separate spherical molecular sieve and powdered molecular sieve through setting up the arc filter screen, and spherical molecular sieve rolls out from the discharging pipe, through reasonable structural design, makes this device shaping effectual, and work efficiency is high.

Description

Ball forming machine for molecular sieve preparation

Technical Field

The utility model relates to the technical field of balling devices, in particular to a balling machine for preparing a molecular sieve.

Background

Natural aluminosilicates exist in nature and have the functions of screening molecules, adsorption, ion exchange and catalysis, the natural substances are called zeolites, the artificially synthesized zeolites are called molecular sieves, the main use of molecular sieves is as an excellent adsorbent and desiccant for the separation and purification of substances, and the more important use is as catalysts and catalyst carriers.

Molecular sieves of some manufacturers are prepared by a pair roller ball making machine, but the surfaces of spheres prepared by the pair roller ball making machine are not smooth, redundant molecular sieve powder exists at the joint gaps of hemispheres, meanwhile, the molecular sieve spheres and the molecular sieve powder come out of a discharge hole together, the next separation and polishing operation procedures are needed, the whole preparation process is complex, and the working efficiency is low.

Accordingly, one skilled in the art provides a ball mill for molecular sieve preparation to solve the above-mentioned problems in the prior art.

Disclosure of Invention

The utility model mainly solves the technical problems existing in the prior art and provides a granulator for preparing molecular sieves.

In order to achieve the above purpose, the utility model adopts the following technical scheme that the balling machine for molecular sieve preparation comprises an equipment box, a feed inlet for feeding is fixedly arranged at the top end of the equipment box, the feed inlet is communicated with the inside of an equipment box cavity, a driving box for installing a driving device is arranged on the front end wall surface of the equipment box, a motor is fixedly arranged on the outer wall surface of the driving box, a supporting table is arranged below the equipment box, a supporting block is clamped below the motor, a discharging pipe for discharging is arranged behind the equipment box, a balling component for preparing the molecular sieve into balls is arranged in the equipment box cavity, the balling component comprises two groups of rotating rollers, a forming component for polishing the spherical molecular sieve is arranged below the rotating rollers, and the forming component comprises a polishing pipe.

Preferably, hemispherical grooves distributed in an annular array are formed in the outer wall surfaces of the two groups of rotating rollers, rotating shafts are fixedly penetrated through the axes of the two groups of rotating rollers, first gears are fixedly penetrated through one side, close to the driving box, of the outer wall surface of the rotating shafts, and the two first gears are movably meshed.

Preferably, one end of the rotating shaft far away from the driving box is movably mounted on a side wall surface in the equipment box cavity through a bearing, one end of the rotating shaft close to the driving box is movably mounted on the inner wall surface of the driving box through a bearing, and an output shaft of the motor movably penetrates through the driving box and is fixedly connected with a rotating shaft.

Preferably, the polishing pipe is in a hollow truncated cone shape, a hollow gear is fixedly arranged on the outer wall surface of the polishing pipe, and a tray is fixedly arranged on the outer wall surface of the polishing pipe through welding.

Preferably, the outer wall surface of the tray is movably connected with a mounting block through a bearing, the mounting block is in a ring shape, and a connecting plate is fixedly connected between the mounting block and the inner wall surface of the equipment box.

Preferably, the hollow gear is movably meshed with a second gear, a long rod is fixedly penetrated on the axis of the second gear, the top end of the long rod is movably mounted on the top end of the inner wall surface of the equipment box through a bearing, a servo motor is fixedly mounted at the bottom end of the cavity of the equipment box, and an output shaft of the servo motor is fixedly connected with one end of the equipment box.

Preferably, an arc filter screen is arranged right below the polishing pipe, the arc filter screen is arc-shaped, the inclined state of the arc filter screen is fixedly arranged in a cavity of the equipment box, one end of the arc filter screen is fixedly connected with the discharging pipe, the arc filter screen is communicated with the discharging pipe, and the discharging pipe is fixedly connected with the rear wall surface of the equipment box.

Advantageous effects

The utility model provides a ball forming machine for preparing a molecular sieve. The beneficial effects are as follows:

(1) This kind of molecular sieve preparation is with granulator, molecular sieve powder enters into the intracavity of equipment box through the feed inlet, prepare the molecular sieve powder into sphericity through setting up the ball subassembly, through setting up forming assembly in the below of ball subassembly, the pipe of polishing constantly rotates can polish spherical molecular sieve for the surface is smooth, can separate spherical molecular sieve and powdered molecular sieve through setting up the arc filter screen, and spherical molecular sieve rolls out from the discharging pipe, through reasonable structural design, make this device shaping effectual, work efficiency is high.

(2) This molecular sieve preparation is with ball forming machine, the pipe of polishing rotates at work, and spherical molecular sieve gets into the intracavity of pipe of polishing and is polished by the pipe of polishing that rotates, is hollow round platform shape through setting up the pipe of polishing, and the binding off of pipe of polishing has effectively improved the effect of polishing downwards, and unnecessary molecular sieve is polished off on the spherical molecular sieve surface for spherical molecular sieve surface is smoother.

(3) This molecular sieve preparation is with granulator, spherical molecular sieve surface after polishing is smooth, spherical molecular sieve mixes together with powdered molecular sieve, needs the staff to select the separation, this process work efficiency is lower, through setting up the arc filter screen in the below of polishing the pipe, the arc filter screen is the arc, arc filter screen incline state fixed mounting is in the intracavity of equipment box, spherical molecular sieve falls in the arc filter screen and rolls out through the discharging pipe, powdered molecular sieve directly falls into the collecting box of below through the arc filter screen and balls again, further improved work efficiency through this structural design.

Drawings

FIG. 1 is a schematic perspective view of a ball mill for preparing molecular sieves;

FIG. 2 is a schematic top view of a ball mill for molecular sieve preparation according to the present utility model;

FIG. 3 is a schematic view of a pelletizing module of a pelletizer for molecular sieve preparation according to the present utility model;

FIG. 4 is a schematic diagram of a forming assembly of a ball mill for molecular sieve preparation according to the present utility model;

FIG. 5 is a schematic view of the mounting structure of a polishing tube of a ball mill for molecular sieve preparation according to the present utility model;

FIG. 6 is a schematic diagram showing the connection between an arc filter screen and a discharge pipe of a ball mill for molecular sieve preparation according to the present utility model.

Legend description:

10. an equipment box; 11. a feed inlet; 12. a drive box; 13. a motor; 14. a support block; 15. a balling assembly; 16. a discharge pipe; 17. a rotating roller; 18. hemispherical grooves; 19. a rotating shaft; 20. a first gear; 21. polishing the tube; 22. a hollow gear; 23. a mounting block; 24. a second gear; 25. a long rod; 26. a servo motor; 27. a tray; 28. a connecting plate; 29. arc filter screen.

Detailed Description

As shown in fig. 1-6: the utility model provides a balling machine for molecular sieve preparation, including equipment box 10, the top fixed mounting of equipment box 10 has the feed inlet 11 that is used for the feeding, feed inlet 11 link up in with the equipment box 10 chamber, equipment box 10 front end wall face is provided with the driving box 12 that is used for installing drive arrangement, fixed mounting has motor 13 on the outer wall face of driving box 12, the below of equipment box 10 is provided with the brace table, the below block of motor 13 has supporting shoe 14, the rear of equipment box 10 is provided with the discharging pipe 16 that is used for the ejection of compact, equipment box 10 intracavity is provided with the balling subassembly 15 that the molecular sieve was prepared into balls, balling subassembly 15 is including rotor 17, rotor 17 is two sets of, rotor 17's below is provided with the shaping subassembly that polishes to spherical molecular sieve, the shaping subassembly is including polishing pipe 21.

Specifically, molecular sieve powder enters into the cavity of the equipment box 10 through the feed inlet 11, is prepared into a sphere through setting up the balling subassembly 15, and through setting up the shaping subassembly in the below of balling subassembly 15, the pipe 21 of polishing constantly rotates and can polish spherical molecular sieve for the surface is smooth, can separate spherical molecular sieve and powdered molecular sieve through setting up arc filter screen 29, and spherical molecular sieve rolls out from discharging pipe 16, through reasonable structural design, makes this device shaping effectual, work efficiency is high.

Hemispherical grooves 18 distributed in an annular array are formed in the outer wall surfaces of the two groups of rotating rollers 17, rotating shafts 19 are fixedly penetrated through the axes of the two groups of rotating rollers 17, first gears 20 are fixedly penetrated through one side, close to the driving box 12, of the outer wall surfaces of the rotating shafts 19, and the two first gears 20 are movably meshed.

Specifically, the two rotating rollers 17 rotate in opposite directions, and hemispherical grooves 18 distributed in an annular array are formed in the outer wall surface of the rotating roller 17, so that the rotating roller 17 combines the two hemispheres into a sphere in the rotating process.

One end of the rotating shaft 19 far away from the driving box 12 is movably mounted on a side wall surface in the cavity of the equipment box 10 through a bearing, one end of the rotating shaft 19 close to the driving box 12 is movably mounted on the inner wall surface of the driving box 12 through a bearing, and an output shaft of the motor 13 movably penetrates through the driving box 12 and is fixedly connected with one rotating shaft 19.

Specifically, the motor 13 drives the rotation shaft 19 and the first gear 20 to rotate, thereby completing the driving of the rotation roller 17.

The polishing tube 21 is in a hollow truncated cone shape, a hollow gear 22 is fixedly arranged on the outer wall surface of the polishing tube 21, and a tray 27 is fixedly arranged on the outer wall surface of the polishing tube 21 through welding.

Specifically, the polishing tube 21 rotates at work, the spherical molecular sieve enters the cavity of the polishing tube 21 and is polished by the rotating polishing tube 21, the polishing tube 21 is in a hollow round table shape, the closing-in of the polishing tube 21 is downward, the polishing effect is effectively improved, and redundant molecular sieves on the outer surface of the spherical molecular sieve are polished off, so that the outer surface of the spherical molecular sieve is smoother.

The outer wall surface of the tray 27 is movably connected with a mounting block 23 through a bearing, the mounting block 23 is circular, and a connecting plate 28 is fixedly connected between the mounting block 23 and the inner wall surface of the equipment box 10.

Specifically, the outer wall surface of the polishing tube 21 is fixedly connected with the tray 27 through welding, the tray 27 can play a supporting role on the polishing tube 21, the tray 27 is movably connected with the mounting block 23 through a bearing, the polishing tube 21 is convenient to rotate, and the mounting block 23, the tray 27 and the equipment box 10 are convenient to fix through the arrangement of the connecting plate 28 blocks.

The hollow gear 22 is movably meshed with a second gear 24, a long rod 25 is fixedly penetrated on the axis of the second gear 24, the top end of the long rod 25 is movably mounted on the top end of the inner wall surface of the equipment box 10 through a bearing, a servo motor 26 is fixedly mounted at the bottom end of the cavity of the equipment box 10, and an output shaft of the servo motor 26 is fixedly connected with one end of the equipment box 10.

Specifically, in operation, the servo motor 26 drives the long rod 25 to rotate, the outer wall surface of the long rod 25 is fixedly penetrated through the second gear 24, and the second gear 24 is movably meshed with the hollow gear 22, so that the second gear 24, the hollow gear 22 and the polishing tube 21 are driven to rotate in the rotation process of the long rod 25, and polishing of the spherical molecular sieve can be completed in the rotation process of the polishing tube 21.

An arc-shaped filter screen 29 is arranged right below the polishing pipe 21, the arc-shaped filter screen 29 is arc-shaped, the arc-shaped filter screen 29 is fixedly installed in a cavity of the equipment box 10 in an inclined state, one end of the arc-shaped filter screen 29 is fixedly connected with the discharging pipe 16, the arc-shaped filter screen 29 is communicated with the discharging pipe 16, and the discharging pipe 16 fixedly penetrates through the rear wall surface of the equipment box 10.

Specifically, spherical molecular sieve surface after polishing is smooth, spherical molecular sieve mixes with powdered molecular sieve and is in the same place, need the staff to select the separation, this process work efficiency is lower, through setting up arc filter screen 29 in the below of polishing pipe 21, arc filter screen 29 is the arc, arc filter screen 29 incline state fixed mounting is in the intracavity of equipment box 10, spherical molecular sieve falls in arc filter screen 29 and rolls out through discharging pipe 16, powdered molecular sieve directly falls into the ball again in the collecting box of below through arc filter screen 29, work efficiency has been further improved through this structural design.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims.

Claims (7)

1. The utility model provides a ball forming machine for molecular sieve preparation, includes equipment box (10), its characterized in that: the utility model discloses a ball forming device for the molecular sieve, including equipment box (10), top fixed mounting of equipment box (10) has feed inlet (11) that are used for the feeding, link up in feed inlet (11) and equipment box (10) chamber, equipment box (10) front end wall face is provided with driving box (12) that are used for installing drive arrangement, fixed mounting has motor (13) on the outer wall face of driving box (12), the below of equipment box (10) is provided with the brace table, the below block of motor (13) has supporting shoe (14), the rear of equipment box (10) is provided with discharging pipe (16) that are used for the ejection of compact, equipment box (10) intracavity is provided with ball forming assembly (15) that are prepared the ball to the molecular sieve, ball forming assembly (15) are including rotor (17), rotor (17) are two sets of, the below of rotor (17) is provided with the shaping subassembly that polishes the spherical molecular sieve, shaping subassembly is including polishing pipe (21).

2. The ball mill for molecular sieve preparation according to claim 1, wherein: hemispherical grooves (18) distributed in an annular array are formed in the outer wall surfaces of the two groups of rotating rollers (17), rotating shafts (19) are fixedly penetrated through the axes of the two groups of rotating rollers (17), first gears (20) are fixedly penetrated through one sides, close to the driving box (12), of the outer wall surfaces of the rotating shafts (19), and the two first gears (20) are movably meshed.

3. The ball mill for molecular sieve preparation according to claim 2, wherein: one end of the rotating shaft (19) far away from the driving box (12) is movably mounted on a side wall surface in a cavity of the equipment box (10) through a bearing, one end of the rotating shaft (19) close to the driving box (12) is movably mounted on the inner wall surface of the driving box (12) through a bearing, and an output shaft of the motor (13) movably penetrates through the driving box (12) and is fixedly connected with the rotating shaft (19).

4. The ball mill for molecular sieve preparation according to claim 1, wherein: the polishing tube (21) is in a hollow truncated cone shape, a hollow gear (22) is fixedly arranged on the outer wall surface of the polishing tube (21), and a tray (27) is fixedly arranged on the outer wall surface of the polishing tube (21) through welding.

5. The ball mill for molecular sieve preparation according to claim 4, wherein: the outer wall surface of the tray (27) is movably connected with a mounting block (23) through a bearing, the mounting block (23) is in a circular ring shape, and a connecting plate (28) is fixedly connected between the mounting block (23) and the inner wall surface of the equipment box (10).

6. The ball mill for molecular sieve preparation according to claim 4, wherein: the hollow gear (22) is movably meshed with a second gear (24), a long rod (25) is fixedly penetrated through the axis of the second gear (24), the top end of the long rod (25) is movably mounted on the top end of the inner wall surface of the equipment box (10) through a bearing, a servo motor (26) is fixedly mounted at the bottom end of the cavity of the equipment box (10), and an output shaft of the servo motor (26) is fixedly connected with one end of the equipment box (10).

7. The ball mill for molecular sieve preparation according to claim 1, wherein: an arc filter screen (29) is arranged right below the polishing pipe (21), the arc filter screen (29) is arc-shaped, the arc filter screen (29) is fixedly installed in a cavity of the equipment box (10) in an inclined state, one end of the arc filter screen (29) is fixedly connected with the discharging pipe (16), the arc filter screen (29) is communicated with the discharging pipe (16), and the discharging pipe (16) is fixedly penetrated through the rear wall surface of the equipment box (10).