CN220004212U - Bio-organic fertilizer grinds pelletization device - Google Patents

Abstract

The utility model relates to the technical field of bio-organic fertilizer grinding, in particular to a bio-organic fertilizer grinding and granulating device, which comprises a baffle plate arranged in a grinding box, wherein the baffle plate divides the grinding box into a filter cavity and a grinding cavity from left to right, and a feed inlet is arranged at the top of the grinding cavity; the grinding plate is driven by the lifting piece and is arranged in the grinding cavity below the feeding hole in a lifting manner, and a grinding component is arranged above the grinding plate; a pushing component is arranged in the grinding cavity below the grinding component at one side of the grinding plate, and the pushing component is arranged opposite to the discharge hole on the partition plate; the vibrating plate is driven by the vibrating mechanism and arranged below the first guide chute in the filter cavity in a vibrating way, a through hole is formed in the vibrating plate, and a discharge pipe is arranged on the side wall of the filter cavity below the vibrating plate; the turnover box is driven by the turnover assembly, and is arranged on the vibrating plate below the first guide chute in a turnover manner, and a filtering hole is formed in the turnover box. The utility model has the advantages of improving the filtration efficiency of the turnover box and the like.

Description

Bio-organic fertilizer grinds pelletization device

Technical Field

The utility model relates to the technical field of bio-organic fertilizer grinding, in particular to a bio-organic fertilizer grinding and granulating device.

Background

The biological organic fertilizer is a fertilizer which is formed by compounding microorganism with specific functions and organic materials which mainly take animal and plant residues (such as livestock manure, crop straws and the like) as sources and are decomposed.

In the production process of the bio-organic fertilizer, the organic fertilizer is required to be ground, the grinding equipment is required to filter the organic fertilizer after grinding the organic fertilizer, the organic fertilizer with larger particles is removed by using the filter plate, the grinding quality of the organic fertilizer is ensured, the blocking phenomenon is easy to occur when the organic fertilizer is filtered by the existing filter plate, and the filtering efficiency of the filter plate is reduced.

Disclosure of Invention

In view of the above, the present utility model provides a bio-organic fertilizer grinding and granulating device, which aims to solve the above problems in the prior art.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: a bio-organic fertilizer grinding and granulating device, comprising:

the grinding box is internally provided with a partition board, the partition board divides the grinding box into a filter cavity and a grinding cavity from left to right, and the top of the grinding cavity is provided with a feed inlet;

the grinding plate is driven by the lifting piece and is arranged in the grinding cavity below the feeding hole in a lifting manner, and a grinding component is arranged above the grinding plate and is used for grinding materials on the grinding plate; a pushing component is arranged in the grinding cavity below the grinding component at one side of the grinding plate, the pushing component is arranged opposite to the discharge hole on the partition plate, and when the upper surface of the grinding plate is flush with the discharge hole, the pushing component pushes the material on the grinding plate from the discharge hole to a first guide chute in the filter cavity;

the vibrating plate is driven by the vibrating mechanism and is arranged below the first guide chute in the filter cavity in a vibrating way, a through hole is formed in the vibrating plate, and a discharge pipe is arranged on the side wall of the filter cavity below the vibrating plate; and

the turnover box is driven by the turnover assembly, the turnover box is arranged on the vibrating plate below the first guide chute, when the turnover box is turned over, materials in the turnover box can be discharged into the collection box through the discharge hole in the filter cavity, and the turnover box is provided with a filter hole.

A further improvement of the present utility model is that the flipping assembly comprises:

the first rotating shaft is rotatably arranged on the vibrating plate under the drive of the first motor;

the rotating sleeve is sleeved on the first rotating shaft;

the lower end of the second rotating shaft is connected with the rotating shaft above the rotating sleeve, and a first bevel gear arranged on the second rotating shaft is meshed with a second bevel gear on the first rotating shaft; and

the connecting block is arranged on one side of the turnover box opposite to the first end of the turnover box and hinged to one side of the turnover box, and the connecting block is in threaded connection with and penetrates through a threaded section on the second rotating shaft.

A further improvement of the present utility model is that the vibration mechanism includes:

the vibrating block is connected with the lower surface of the vibrating plate through a connecting shaft arranged at the upper end and connected with the bottom of the filter cavity through a telescopic component at the lower end;

the double-shaft motor is horizontally arranged on the vibrating block; two first eccentric wheels are symmetrically arranged on the two power output ends;

the third rotating shaft is rotatably arranged on the vibrating block in parallel with the double-shaft motor, and two second eccentric wheels are symmetrically arranged at two ends of the third rotating shaft respectively; and

and the first gear is connected with one end of the double-shaft motor and meshed with a second gear arranged on the third rotating shaft.

A further improvement of the present utility model is that the telescoping assembly comprises:

the support column is arranged below the vibrating block;

the first end of the supporting cylinder is connected with the bottom of the filter cavity, and the upper end of the supporting cylinder is sleeved on the supporting column; and

the spring is arranged in the supporting cylinder, the first end of the spring is connected with the bottom of the supporting cylinder, and the second end of the spring is connected with the lower end of the supporting column.

The utility model further improves that the grinding assembly comprises a grinding frame which is arranged above the grinding plate in a horizontal moving way under the drive of the moving assembly, and a grinding roller is arranged below the grinding frame.

A further improvement of the present utility model is that the moving assembly comprises:

the screw rod is driven by the second motor, is rotatably and horizontally arranged above the grinding frame, and is in threaded connection with and penetrates through the grinding frame; and

the optical axis is arranged in parallel with the screw rod, and is connected with the grinding frame in a sliding way and penetrates through the grinding frame.

The utility model further improves that the pushing component comprises a pushing plate, and the pushing plate is driven by the air cylinder to be far away from or near to the discharging hole and arranged below the grinding component at one side of the grinding plate.

The utility model is further improved in that the lifting piece is a hydraulic cylinder, the hydraulic cylinder is arranged below the grinding plate, and the upper end of a piston rod of the hydraulic cylinder is connected with the lower surface of the grinding plate.

The utility model further improves that the bottom of the filter cavity is provided with a slope, and the discharge pipe is arranged opposite to the lower end of the slope.

The utility model is further improved in that the discharge opening is arranged on a partition plate below the hydraulic cylinder, a drawable collecting box is arranged in a grinding cavity below the discharge opening, an inclined second guide chute is arranged below the overturning box, the higher end of the second guide chute is arranged below the overturning box, and the lower end of the second guide chute is level with the lower end of the discharge opening.

By adopting the technical scheme, the utility model has the following technical progress:

the utility model provides a bio-organic fertilizer grinding and granulating device, wherein a lifting part is used for lifting a grinding plate to a grinding assembly, then conveying materials from a feeding hole to the grinding plate, the grinding assembly is used for grinding the materials on the grinding plate, the lifting part is used for lowering the grinding plate to be flush with the lower end of a discharge hole after the grinding is finished, a pushing component is used for pushing the materials on the grinding plate to a first guide groove in a filter cavity from the discharge hole, the first guide groove is used for conveying the materials to a turnover box, then a vibrating mechanism is used for driving the turnover box to vibrate through a vibrating plate, the materials in the turnover box can be effectively filtered, the materials meeting the requirements are enabled to fall to the bottom of the filter cavity through the filter hole and then are discharged from a discharge pipe, the turnover box is driven by the turnover assembly to turn over the materials with larger particles, the materials with larger particles are conveyed into a second guide groove and a discharge hole, and the materials with larger particles in the collection box are ground again, and compared with the prior art, the filter efficiency of the turnover box can be effectively maintained, and the popularization value is extremely high.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort to a person skilled in the art.

FIG. 1 is a schematic view of the overall structure of the grinding and granulating apparatus according to the present utility model;

FIG. 2 is a schematic diagram of the turnover assembly of the grinding and granulating device according to the present utility model;

FIG. 3 is a schematic view of a vibration mechanism of the grinding and granulating device according to the present utility model;

FIG. 4 is a schematic view of a moving assembly of the grinding and granulating apparatus according to the present utility model;

reference numerals illustrate:

10-grinding box, 101-feeding port, 102-discharging pipe, 11-partition plate, 111-discharging port, 112-first guide groove, 113-discharging port, 114-second guide groove, 12-grinding plate, 121-hydraulic cylinder, 13-pushing plate, 131-cylinder, 14-vibrating plate, 141-through hole, 15-turning box, 151-filtering hole, 16-grinding frame, 161-grinding roller, 17-slope, 18-collecting box, 20-turning component, 21-first rotating shaft, 22-first motor, 23-rotating sleeve, 24-second rotating shaft, 241-first bevel gear, 242-second bevel gear, 25-connecting block, 30-vibrating mechanism, 301-vibrating block, 31-double shaft motor, 32-first eccentric wheel, 33-third rotating shaft, 34-second eccentric wheel, 35-first gear, 36-second gear, 40-telescoping component, 41-supporting column, 42-supporting cylinder, 43-spring, 50-moving component, 51-screw, 52-second motor, 53-optical axis.

Detailed Description

Technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it should be apparent that in the following description, specific details are set forth such as the specific system structure, technology, etc. for the purpose of illustration rather than limitation, in order to provide a thorough understanding of the embodiments of the present utility model. It will be apparent, however, to one skilled in the art that the present utility model may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known systems, devices, circuits, and methods are omitted so as not to obscure the description of the present utility model with unnecessary detail.

The utility model provides a bio-organic fertilizer grinding and granulating device, which is known by combining the accompanying drawings 1 to 4 in the specification, and mainly comprises the following parts or components: grinding box 10, grinding plate 12, vibration plate 14, and turn box 15.

In the utility model, a baffle plate 11 is arranged in a grinding box 10, the baffle plate 11 divides the grinding box 10 into a filter cavity and a grinding cavity from left to right, and a feed inlet 101 is arranged at the top of the grinding cavity; the grinding plate 12 is driven by a lifting piece, is arranged in a grinding cavity below the feeding hole 101 in a lifting manner, and a grinding component is arranged above the grinding plate 12 and is used for grinding materials on the grinding plate 12; a pushing component is arranged in the grinding cavity below the grinding component at one side of the grinding plate 12 and is opposite to the discharge hole 111 on the partition plate 11, and when the upper surface of the grinding plate 12 is level to the discharge hole 111, the pushing component pushes the material on the grinding plate 12 from the discharge hole 111 to the first guide chute 112 in the filter cavity; the vibrating plate 14 is driven by the vibrating mechanism 30, and is arranged below the first guide chute 112 in the filter cavity in a vibrating way, a through hole 141 is arranged on the vibrating plate 14, and a discharge pipe 102 is arranged on the side wall of the filter cavity below the vibrating plate 14; the turnover box 15 is driven by the turnover assembly 20 to be arranged on the vibrating plate 14 below the first guide chute 112 in a turnover manner, when the turnover box 15 is turned over, materials in the turnover box 15 can be discharged into the collection box 18 through the discharge hole 113 in the filter cavity, and the turnover box 15 is provided with the filter hole 151. The discharge opening 113 is arranged on the partition plate 11 below the hydraulic cylinder 121, a drawable collecting box 18 is arranged in the grinding cavity below the discharge opening 113, an inclined second guide chute 114 is arranged below the overturning box 15, the higher end of the second guide chute 114 is arranged below the overturning box 15, and the lower end of the second guide chute 114 is level with the lower end of the discharge opening 113.

In operation, the utility model provides a bio-organic fertilizer grinding and granulating device, after a grinding plate 12 is lifted to a grinding component through a lifting part, materials are conveyed to the grinding plate 12 from a feeding hole, the grinding component grinds the materials on the grinding plate 12, after finishing grinding, the lifting part lowers the grinding plate 12 to be flush with the lower end of a discharging hole 111, a pushing component pushes the materials on the grinding plate 12 to a first guide groove 112 in a filter cavity from the discharging hole 111, the first guide groove 112 conveys the materials to a turnover box 15, then a vibrating mechanism 30 drives the turnover box 15 to vibrate through a vibrating plate 14, the materials in the turnover box 15 can be effectively filtered, the materials meeting the requirements are discharged from a discharge pipe 102 after falling to the bottom of the filter cavity through a filtering hole 151 and a through hole 141, the materials with larger particles are driven to turn over the turnover box 15 through the turnover component 20, the materials with larger particles are conveyed into a second guide groove and a discharge hole 113 to be collected in a collection box 18, and the materials with larger particles in the collection box 18 are ground again, and the filtering efficiency of the turnover box 15 can be effectively maintained.

The lifting piece is a hydraulic cylinder 121, the hydraulic cylinder 121 is arranged below the grinding plate 12, and the upper end of a piston rod of the hydraulic cylinder 121 is connected with the lower surface of the grinding plate 12.

Wherein, the pushing component comprises a pushing plate 13, and is driven by a cylinder 131 to be far away from or near to the discharging hole 111 and below the grinding component arranged on one side of the grinding plate 12. The piston rod of the air cylinder 131 pushes the pushing rod, the pushing rod pushes the material on the grinding plate 12 from the discharge hole 111 to the first guide chute 112 in the filter cavity,

as an example, as shown in fig. 2 in conjunction with the specification, the flipping assembly 20 includes a first rotating shaft 21 rotatably disposed on the vibration plate 14 under the driving of a first motor 22; the rotating sleeve 23 is sleeved on the first rotating shaft 21; the lower end of the second rotating shaft 24 is connected with a rotating shaft above the rotating sleeve 23, and a first bevel gear 241 arranged on the second rotating shaft is meshed with a second bevel gear 242 on the first rotating shaft 21; the connecting block 25 is arranged on one side of the turnover box 15 opposite to the first end of the turnover box 15 and hinged with one side of the turnover box 15, and the connecting block 25 is in threaded connection with and penetrates through the threaded section on the second rotating shaft 24.

The first motor 22 drives the first rotating shaft 21 to rotate, the first rotating shaft 21 is meshed with the second bevel gear 242 through the first bevel gear 241 to drive the second rotating shaft 24 to rotate, the connecting block 25 is driven to lift through the rotation of the second rotating shaft 24, and when the connecting block 25 lifts, the first end of the turnover box 15 is hinged with the vibrating plate 14, and the rotating sleeve 23 is connected with the rotating shaft of the first rotating shaft 21, so that the turnover box 15 is gradually inclined when the connecting block 25 lifts, and the turnover is completed.

As an example, as shown in fig. 3 in conjunction with the specification, the vibration mechanism 30 includes a vibration block 301 connected to the lower surface of the vibration plate 14 through a connecting shaft provided at the upper end, and connected to the bottom of the filter chamber through a telescopic assembly 40 at the lower end; the biaxial motor 31 is horizontally arranged on the vibrating block 301; and two first eccentric wheels 32 are symmetrically arranged on the two power output ends; the third rotating shaft 33 is rotatably arranged on the vibrating block 301 in parallel with the double-shaft motor 31, and two second eccentric wheels 34 are symmetrically arranged at two ends of the third rotating shaft 33 respectively; the first gear 35 is connected to one end of the biaxial motor 31 and is meshed with a second gear 36 provided on the third rotation shaft 33.

The double-shaft motor 31 drives the two first eccentric wheels 32 to rotate, and simultaneously, the first gear 35 and the second gear 36 are matched, so that the third rotating shaft 33 can drive the two second eccentric wheels 34 to rotate simultaneously, the rotating fit telescopic assembly 40 of the second eccentric wheels 34 of the first eccentric wheels 32 can drive the vibrating block 301 to vibrate, the vibrating block 301 drives the vibrating plate 14 to vibrate through the connecting shaft, the vibrating plate 14 drives the overturning box 15 to vibrate, and materials in the overturning box 15 can be effectively filtered.

Specifically, the first gear 35 and the second gear 36 have the same number of teeth, the first eccentric wheel 32 and the second eccentric wheel 34 are the same, and the first eccentric wheel 32 and the second eccentric wheel 34 synchronously rotate to the lowest point.

In this embodiment, as can be seen in fig. 3 in conjunction with the description, the telescopic assembly 40 includes a support column 41 disposed below the vibrating block 301; the first end of the supporting cylinder 42 is connected with the bottom of the filter cavity, and the upper end of the supporting cylinder 42 is sleeved on the supporting column 41; the spring 43 is disposed in the support cylinder 42, and has a first end connected to the bottom of the support cylinder 42 and a second end connected to the lower end of the support column 41.

When the vibration block 301 descends, the support column 41 is driven to descend, the support column 41 compresses the spring 43 in the support cylinder 42, the spring 43 is compressed to a certain extent and then stretched, so that the support column 41 and the vibration block 301 are driven to ascend, and the support cylinder 42 can play a guiding role.

As an example, as shown in fig. 4 in conjunction with the specification, the polishing assembly includes a polishing frame 16, and is horizontally movably disposed above the polishing plate 12 under the driving of a moving assembly 50, and a polishing roller 161 is disposed below the polishing frame 16; the moving assembly 50 comprises a screw rod 51 which is rotatably and horizontally arranged above the grinding frame 16 under the drive of a second motor 52, and the screw rod 51 is in threaded connection with and penetrates through the grinding frame 16; the optical axis 53 is disposed parallel to the screw 51, and slidably connected to and penetrates the polishing frame 16.

The second motor 52 drives the screw rod 51 to rotate, the screw rod 51 drives the grinding frame 16 to horizontally move, the grinding frame 16 drives the grinding roller 161 to grind the materials on the grinding plate 12, and the optical axis 53 can keep the balance of the grinding frame 16 during running.

As an example, as can be seen in fig. 1 in conjunction with the description, the bottom of the filter cavity is provided with a slope 17, and the discharge pipe 102 is opposite to the lower end of the slope 17. The material may be conveniently discharged from the discharge tube 102.

It should be noted that in this patent application, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus, does not include, without limitation, additional elements that are defined by the term "include" an.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model, and are intended to be included in the scope of the present utility model.

Claims (10)

1. A bio-organic fertilizer grinding and granulating device, comprising:

the grinding box is internally provided with a partition board, the partition board divides the grinding box into a filter cavity and a grinding cavity from left to right, and the top of the grinding cavity is provided with a feed inlet;

the grinding plate is driven by the lifting piece and is arranged in the grinding cavity below the feeding hole in a lifting manner, and a grinding component is arranged above the grinding plate and is used for grinding materials on the grinding plate; a pushing component is arranged in the grinding cavity below the grinding component at one side of the grinding plate, the pushing component is arranged opposite to the discharge hole on the partition plate, and when the upper surface of the grinding plate is flush with the discharge hole, the pushing component pushes the material on the grinding plate from the discharge hole to a first guide chute in the filter cavity;

the vibrating plate is driven by the vibrating mechanism and is arranged below the first guide chute in the filter cavity in a vibrating way, a through hole is formed in the vibrating plate, and a discharge pipe is arranged on the side wall of the filter cavity below the vibrating plate; and

the turnover box is driven by the turnover assembly, the turnover box is arranged on the vibrating plate below the first guide chute, when the turnover box is turned over, materials in the turnover box can be discharged into the collection box through the discharge hole in the filter cavity, and the turnover box is provided with a filter hole.

2. A bio-organic fertilizer grinding and granulating device according to claim 1, wherein,

the flip assembly includes:

the first rotating shaft is rotatably arranged on the vibrating plate under the drive of the first motor;

the rotating sleeve is sleeved on the first rotating shaft;

the lower end of the second rotating shaft is connected with the rotating shaft above the rotating sleeve, and a first bevel gear arranged on the second rotating shaft is meshed with a second bevel gear on the first rotating shaft; and

the connecting block is arranged on one side of the turnover box opposite to the first end of the turnover box and hinged to one side of the turnover box, and the connecting block is in threaded connection with and penetrates through a threaded section on the second rotating shaft.

3. A bio-organic fertilizer grinding and granulating device according to claim 1, wherein,

the vibration mechanism includes:

the vibrating block is connected with the lower surface of the vibrating plate through a connecting shaft arranged at the upper end and connected with the bottom of the filter cavity through a telescopic component at the lower end;

the double-shaft motor is horizontally arranged on the vibrating block; two first eccentric wheels are symmetrically arranged on the two power output ends;

the third rotating shaft is rotatably arranged on the vibrating block in parallel with the double-shaft motor, and two second eccentric wheels are symmetrically arranged at two ends of the third rotating shaft respectively; and

and the first gear is connected with one end of the double-shaft motor and meshed with a second gear arranged on the third rotating shaft.

4. A bio-organic fertilizer grinding and granulating device according to claim 3, wherein,

the telescoping assembly includes:

the support column is arranged below the vibrating block;

the first end of the supporting cylinder is connected with the bottom of the filter cavity, and the upper end of the supporting cylinder is sleeved on the supporting column; and

the spring is arranged in the supporting cylinder, the first end of the spring is connected with the bottom of the supporting cylinder, and the second end of the spring is connected with the lower end of the supporting column.

5. A bio-organic fertilizer grinding and granulating device according to claim 1, wherein,

the grinding assembly comprises a grinding frame, the grinding frame is arranged above the grinding plate in a horizontally movable mode under the driving of the moving assembly, and a grinding roller is arranged below the grinding frame.

6. A bio-organic fertilizer grinding and granulating apparatus according to claim 5, wherein,

the moving assembly includes:

the screw rod is driven by the second motor, is rotatably and horizontally arranged above the grinding frame, and is in threaded connection with and penetrates through the grinding frame; and

the optical axis is arranged in parallel with the screw rod, and is connected with the grinding frame in a sliding way and penetrates through the grinding frame.

7. A bio-organic fertilizer grinding and granulating device according to claim 1, wherein,

the pushing assembly comprises a pushing plate, and the pushing plate is driven by the air cylinder to be far away from or close to the discharging hole and arranged below the grinding assembly on one side of the grinding plate.

8. A bio-organic fertilizer grinding and granulating device according to claim 1, wherein,

the lifting piece is a hydraulic cylinder, the hydraulic cylinder is arranged below the grinding plate, and the upper end of a piston rod of the hydraulic cylinder is connected with the lower surface of the grinding plate.

9. A bio-organic fertilizer grinding and granulating device according to claim 1, wherein,

the bottom of the filter cavity is provided with a slope, and the discharge pipe is arranged opposite to the lower end of the slope.

10. The bio-organic fertilizer grinding and granulating device according to claim 8, wherein,

the material discharging port is arranged on the partition plate below the hydraulic cylinder, a drawable collecting box is arranged in the grinding cavity below the material discharging port, an inclined second guide chute is arranged below the overturning box, the higher end of the second guide chute is arranged below the overturning box, and the lower end of the second guide chute is flush with the lower end of the material discharging port.