CN210632229U

CN210632229U - High-efficient ball-milling device

Info

Publication number: CN210632229U
Application number: CN201921494219.6U
Authority: CN
Inventors: 刘云华
Original assignee: Pingxiang Xuhua Electric Porcelain Manufacturing Co ltd
Current assignee: Pingxiang Xuhua Electric Porcelain Manufacturing Co ltd
Priority date: 2019-09-09
Filing date: 2019-09-09
Publication date: 2020-05-29
Anticipated expiration: 2029-09-09

Abstract

The utility model discloses a high-efficiency ball milling device, which belongs to the technical field of ball milling devices and comprises a shell, wherein a bearing is clamped on the left side surface of the shell, a rotating shaft is sleeved in the bearing, the left end of the rotating shaft is fixedly connected with an output shaft of a motor a, the upper surface and the lower surface of the motor a are fixedly connected with the left side surface of the shell through a mounting plate, the motor a is electrically connected with an external control switch, and the upper surface of the shell is provided with a feeding hopper; through setting up casing and filter screen a, can put into the ball of variation in size in the casing, large-scale ball is located filter screen a's left side, small-size ball is located filter screen a's right side, through setting up stirring board a, the lapping plate can be fixed to the net bucket, the lapping plate can carry out the third time correct grinding with the inner wall that goes out the hopper to the raw materials, the raw materials can be followed the slow spill in the net bucket simultaneously, thereby make the raw materials can slowly spill and can not cause the jam, make the effect of the third time correct grinding better.

Description

High-efficient ball-milling device

Technical Field

The utility model belongs to the technical field of the ball-milling device, concretely relates to high-efficient ball-milling device.

Background

The ball mill is a key device for crushing materials after the materials are crushed, is mainly applied to the production industries of cement, silicate products, novel building materials, refractory materials, chemical fertilizers, black and non-ferrous metal ore dressing, glass ceramics and the like, can be divided into a dry type ore grinding mode and a wet type ore grinding mode according to different ore discharging modes, is suitable for grinding various ores and other materials, and is widely applied to the industries of ore dressing, building materials, chemical engineering and the like.

According to the 'glaze making ball mill for ceramic insulator' (patent number: CN201721561878.8), the scheme records that 'the working efficiency of the ball mill is effectively improved by arranging a rotary paddle, the grinding effect and the grinding degree of the ball mill are effectively improved, a motor drives a barrel to rotate, simultaneously, steel balls in a grinding medium steel ball layer are driven to fall down to generate the heavy impact and grinding effects on materials, the steel balls and the materials are effectively driven to move by the rotary paddle to overturn, so that the collision is stronger, the grinding force of the steel balls is effectively enhanced, the grinding time of the grinding materials is effectively saved, the working efficiency is effectively improved', however, the scheme can only carry out ball milling on the raw materials in one mode, if qualified conditions are required, the raw materials need to be subjected to ball milling for multiple times, and the processing time of the raw materials is longer, the ball milling efficiency of the raw materials is reduced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient ball-milling device to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a high-efficiency ball milling device comprises a shell, wherein a bearing is clamped on the left side surface of the shell, a rotating shaft is sleeved in the bearing, the left end of the rotating shaft is fixedly connected with an output shaft of a motor a, the upper surface and the lower surface of the motor a are fixedly connected with the left side surface of the shell through a mounting plate, the motor a is electrically connected with an external control switch, a feed hopper is arranged on the upper surface of the shell, a plurality of stirring plates a and grinding rods are fixedly connected to the outer surface of the rotating shaft, the stirring plates a and the grinding rods are respectively positioned on the left side and the right side of a filter screen a, the outer surface of the filter screen a is fixedly connected with the inner wall of the shell, a limiting hole is formed in the left side surface of the filter screen a, the rotating shaft is positioned in the limiting hole, a plurality of stirring plates b are uniformly and fixedly connected to, the position fixedly connected with net bucket that the casing right flank corresponds filter screen b, the surface of net bucket has cup jointed the bearing, and bearing fixed connection is at the inner wall of play hopper, the left surface that goes out the hopper and the right flank laminating of casing.

By adopting the scheme, a worker can put grinding balls with different sizes in the shell, a large grinding ball is positioned on the left side of the filter screen a, a small grinding ball is positioned on the right side of the filter screen a, raw materials are added into the shell through the feed hopper, then the motor a is controlled to work to drive the rotating shaft to rotate, the rotating shaft can drive the stirring plate a and the grinding rod to rotate, the stirring plate a can stir the large ball grinding and the raw materials, the large ball grinding is heavier, the raw materials on the left side of the filter screen a can be easily smashed, the raw materials are subjected to primary coarse grinding, the raw materials with qualified sizes can enter the right side of the filter screen a through the filter screen a, the stirring plate b can drive the small ball grinding and the raw materials to move in the shell, so that the raw materials can generate extrusion friction with the grinding rod and the inner wall of the small ball grinding and the shell, and spill in the net bucket, the work of simultaneous control motor b, motor b during operation can drive gear a rotatory, gear a can effectively drive out the hopper rotation through gear b, the lapping plate can carry out the fine grinding for the third time with the inner wall that goes out the hopper to the raw materials, qualified raw materials of fine grinding can spill through filter screen c, in the grinding process, control shock dynamo work, the casing can be pushed up to the shock dynamo during operation, make the casing produce vibrations from top to bottom, vibrations can make the raw materials rock at will in the casing, help the material change position and make the grinding effect better, filter screen a is plugged up to the avoidance raw materials that simultaneously can be fine, filter screen b, the mesh on filter screen b and the net bucket.

In the above scheme, it should be noted that the model of the motor a and the model of the motor b may be Y2-132M-4; the vibration motor may be model yzu 8-6.

In a preferred embodiment, the left and right sides of the front and back of the housing are fixedly connected with supporting plates, and the lower surfaces of the supporting plates are fixedly connected with the upper surface of the bottom plate through spring rods.

By adopting the scheme, the shell can drive the spring rod to extend or contract when moving up and down by arranging the spring rod, so that the shell is more stable when moving up and down.

As a preferred embodiment, the spring rod is composed of a spring and a telescopic rod, the spring is sleeved on the outer surface of the telescopic rod, and the top ends and the bottom ends of the spring and the telescopic rod are respectively fixedly connected with the opposite surfaces of the supporting plate and the bottom plate.

Adopt above-mentioned scheme, through setting up spring and telescopic link, the spring can be through self elasticity shrink, can effectively pull back the casing of rebound, can drive the telescopic link extension or shrink when the casing reciprocates for the casing is more stable when reciprocating.

As a preferred embodiment, the upper surface of the bottom plate is fixedly connected with a vibration motor, the upper surface of the vibration motor is attached to the lower surface of the stop block, the stop block is fixedly connected to the lower surface of the casing, and the vibration motor is electrically connected with the external control switch.

Adopt above-mentioned scheme, through setting up shock dynamo, shock dynamo during operation can push up the casing for the casing can produce vibrations from top to bottom, and vibrations can make the raw materials rock at will in the casing, help the material change position and make the grinding effect better, and mesh on avoiding the raw materials to plug up filter screen a, filter screen b and the net bucket that simultaneously can be fine.

As a preferred embodiment, a gear b is fixedly connected to the outer surface of the discharge hopper, the gear b is meshed with the gear a, the left side surface of the gear a is fixedly connected with an output shaft of a motor b, the motor b is fixedly connected to the upper surface of the shell, and the motor b is electrically connected with an external control switch.

By adopting the scheme, the motor b can drive the gear a to rotate when working by arranging the gear a and the gear b, and the gear a can effectively drive the discharge hopper to rotate through the gear b.

As a preferred embodiment, a plurality of grinding plates are fixedly connected to the outer surface of the net barrel, a filter screen c is arranged below the grinding plates, and the outer surface of the filter screen c is fixedly connected with the inner wall of the discharge hopper.

Adopt above-mentioned scheme, through setting up the lapping plate, the lapping plate can carry out the fine grinding of the third time with the inner wall of play hopper to the raw materials, and through setting up filter screen c, unqualified raw materials can be plugged up to filter screen c for the raw materials can be ground to the qualification in going out the hopper repeatedly.

In a preferred embodiment, the diameter of the mesh of the filter screen c is smaller than that of the mesh of the filter screen b, the diameter of the mesh of the filter screen c is the same as that of the mesh of the filter screen b, and the diameter of the mesh of the filter screen b is smaller than that of the mesh of the filter screen a.

By adopting the scheme, the raw materials can sequentially pass through the filter screen a, the filter screen b, the screen barrel and the filter screen c from large to small, so that the ball milling of the raw materials is not influenced.

Compared with the prior art, the beneficial effects of the utility model are that:

the high-efficiency ball milling device is provided with a shell and a filter screen a, grinding balls with different sizes can be placed in the shell, a large grinding ball is positioned on the left side of the filter screen a, a small grinding ball is positioned on the right side of the filter screen a, a stirring plate a can stir large ball milling and raw materials, the large ball milling is heavier in weight and can easily break the raw materials on the left side of the filter screen a, the raw materials are subjected to primary coarse grinding, the raw materials with qualified sizes can enter the right side of the filter screen a through the filter screen a, the stirring plate b can drive the small ball milling and the raw materials to move in the shell through the arrangement of a grinding rod and a stirring plate b, so that the raw materials can generate extrusion friction with the grinding rod, the small ball milling and the inner wall of the shell, further secondary fine grinding is formed, the grinding plate can be fixed by the mesh bucket, and the grinding plate can perform tertiary fine grinding on, meanwhile, the raw materials can slowly leak out of the mesh bucket, so that the raw materials can slowly leak out without blockage, and the effect of the third fine grinding is better;

this high-efficient ball-milling device is through setting up shock dynamo, and shock dynamo during operation can push up the casing for the casing can produce vibrations from top to bottom, and vibrations can make the raw materials rock at will in the casing, help the material change position and make the grinding effect better, and mesh on filter screen an, filter screen b and the net bucket is plugged up to the raw materials of avoiding that simultaneously can be fine.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic top view of the present invention;

fig. 3 is a schematic view of the front view section structure of the middle discharge hopper of the present invention.

In the figure: 1. a housing; 2. a filter screen a; 3. a rotating shaft; 4. a stirring plate a; 5. a motor a; 6. a feed hopper; 7. a motor b; 8. a gear a; 9. a gear b; 10. a discharge hopper; 11. a filter screen b; 12. a stirring plate b; 13. a grinding rod; 14. vibrating a motor; 15. a spring lever; 151. a telescopic rod; 152. a spring; 16. a support plate; 17. a bearing; 18. a grinding plate; 19. a net barrel; 20. and a filter screen c.

Detailed Description

The present invention will be further described with reference to the following examples.

The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention. The condition in the embodiment can be further adjusted according to concrete condition the utility model discloses a it is right under the design prerequisite the utility model discloses a simple improvement of method all belongs to the utility model discloses the scope of claiming.

The utility model provides a high-efficiency ball milling device, please refer to fig. 1-3, which comprises a shell 1, wherein the left and right sides of the front and back of the shell 1 are fixedly connected with supporting plates 16, and the lower surfaces of the supporting plates 16 are fixedly connected with the upper surface of a bottom plate through spring rods 15 (see fig. 1); through setting up spring beam 15, can drive spring beam 15 extension or shrink when casing 1 reciprocates for casing 1 is more stable when reciprocating.

The spring rod 15 consists of a spring 152 and an expansion rod 151, the spring 152 is sleeved on the outer surface of the expansion rod 151, and the top ends and the bottom ends of the spring 152 and the expansion rod 151 are respectively fixedly connected with the opposite surfaces of the support plate 16 and the bottom plate (see fig. 1); through setting up spring 152 and telescopic link 151, spring 152 can be through the shrink of self elasticity, can effectively pull back casing 1 of rebound, can drive telescopic link 151 extension or shrink when casing 1 reciprocates for casing 1 is more stable when reciprocating.

The left side surface of the shell 1 is clamped with a bearing 17, the rotating shaft 3 is sleeved in the bearing 17, the left end of the rotating shaft 3 is fixedly connected with an output shaft of the motor a5, the upper surface and the lower surface of the motor a5 are fixedly connected with the left side surface of the shell 1 through a mounting plate, the motor a5 is electrically connected with an external control switch, the upper surface of the shell 1 is provided with a feed hopper 6, the upper surface of a bottom plate is fixedly connected with a vibration motor 14, the upper surface of the vibration motor 14 is attached to the lower surface of a stop block, the stop block is fixedly connected to the lower surface of the shell 1, and the vibration motor 14 is electrically connected with the external control switch; through setting up shock dynamo 14, shock dynamo 14 during operation can push up casing 1 for casing 1 can produce vibrations from top to bottom, and vibrations can make the raw materials rock at will in casing 1, help the material change position and make the grinding effect better, and mesh on avoiding the raw materials to plug up filter screen a2, filter screen b11, filter screen b11 and the net bucket 19 that simultaneously can be fine.

The outer surface of the rotating shaft 3 is fixedly connected with a plurality of stirring plates a4 and grinding rods 13, the stirring plates a4 and the grinding rods 13 are respectively positioned at the left side and the right side of a filter screen a2, the outer surface of the filter screen a2 is fixedly connected with the inner wall of the shell 1, the left side surface of the filter screen a2 is provided with a limiting hole, the diameter of a mesh of a filter screen c20 is smaller than that of a mesh barrel 19, the diameter of the mesh barrel 19 is the same as that of a mesh of a filter screen b11, and the diameter of a mesh of the filter screen b11 is smaller than that of the mesh of the filter screen a 2; the raw materials can sequentially pass through a filter screen a2, a filter screen b11, a screen barrel 19 and a filter screen c20 from large to small, so that the ball milling of the raw materials is not influenced.

The rotating shaft 3 is positioned in the limiting hole, the outer surface of the grinding rod 13 is uniformly and fixedly connected with a plurality of stirring plates b12, the right side surface of the shell 1 is clamped with a filter screen b11, the right side surface of the shell 1 is fixedly connected with a net barrel 19 at a position corresponding to the filter screen b11, the outer surface of the net barrel 19 is fixedly connected with a plurality of grinding plates 18, a filter screen c20 is arranged below the grinding plates 18, and the outer surface of the filter screen c20 is fixedly connected with the inner wall of the discharge hopper 10 (see fig. 3); through setting up grinding plate 18, grinding plate 18 can carry out the fine grinding for the third time with the inner wall of play hopper 10 to the raw materials, and through setting up filter screen c20, unqualified raw materials can be stopped up to filter screen c20 for the raw materials can be ground to the qualification repeatedly in going out hopper 10.

The bearing 17 is sleeved on the outer surface of the mesh barrel 19, the bearing 17 is fixedly connected to the inner wall of the discharge hopper 10, the left side surface of the discharge hopper 10 is attached to the right side surface of the housing 1, the outer surface of the discharge hopper 10 is fixedly connected with a gear b9, a gear b9 is meshed with a gear a8, the left side surface of a gear a8 is fixedly connected with an output shaft of a motor b7, a motor b7 is fixedly connected to the upper surface of the housing 1, and a motor b7 is electrically connected with an external control switch (see fig. 1 and 2); through setting up gear a8 and gear b9, motor b7 can drive gear a8 rotatory when working, and gear a8 can effectively drive out hopper 10 rotatory through gear b 9.

When the grinding device is used, workers can put grinding balls with different sizes into the shell 1, a large grinding ball is positioned on the left side of the filter screen a2, a small grinding ball is positioned on the right side of the filter screen a2, raw materials are added into the shell 1 through the feed hopper 6, then the motor a5 is controlled to work to drive the rotating shaft 3 to rotate, the rotating shaft 3 can drive the stirring plate a4 and the grinding rod 13 to rotate, the stirring plate a4 can stir the large ball mill and the raw materials, the large ball mill is heavier in weight and can easily smash the raw materials on the left side of the filter screen a2, the raw materials are subjected to primary coarse grinding, the raw materials with qualified sizes can enter the right side of the filter screen a2 through the filter screen 56fa, the stirring plate b12 can drive the small ball mill and the raw materials to move in the shell 1, so that the raw materials can generate extrusion friction with the grinding rod 13 and the inner wall of the shell 1, thereby forming secondary fine grinding, and spill in net bucket 19, control motor b7 work simultaneously, motor b7 during operation can drive gear a8 rotatory, gear a8 can effectively drive out hopper 10 rotatory through gear b9, lapping plate 18 can carry out the fine grinding of the third time to the raw materials with the inner wall that goes out hopper 10, the qualified raw materials of fine grinding can spill through filter screen c20, in the course of grinding, control shock dynamo 14 work, shock dynamo 14 during operation can push up casing 1, make casing 1 produce vibrations from top to bottom, vibrations can make the raw materials rock at will in casing 1, help the material change position and make the grinding effect better, simultaneously can be fine avoid the raw materials to block up filter screen a2, filter screen b11, filter screen b11 and the mesh on the net bucket 19.

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

1. The utility model provides a high-efficient ball-milling device, includes casing (1), its characterized in that: the left side of casing (1) joint has bearing (17), and has cup jointed pivot (3) in bearing (17), the left end of pivot (3) and the output shaft fixed connection of motor a (5), and the upper surface of motor a (5) and the left surface fixed connection of lower surface all through mounting panel and casing (1), motor a (5) and external control switch electric connection, the upper surface of casing (1) is provided with feeder hopper (6), the outer fixed surface of pivot (3) is connected with a plurality of stirring board a (4) and grinding rod (13), stirring board a (4) and grinding rod (13) are located the left and right sides of filter screen a (2) respectively, the surface of filter screen a (2) and the inner wall fixed connection of casing (1), and the left surface of filter screen a (2) has all seted up spacing hole, pivot (3) are located spacing downthehole, the even fixedly connected with a plurality of stirring board b (12) of surface of grinding rod (13), the right flank joint of casing (1) has filter screen b (11), casing (1) right flank corresponds position fixedly connected with net bucket (19) of filter screen b (11), bearing (17) have been cup jointed to the surface of net bucket (19), and bearing (17) fixed connection is at the inner wall that goes out hopper (10), the left surface that goes out hopper (10) and the right flank laminating of casing (1).

2. The high efficiency ball milling apparatus of claim 1, wherein: the left and right sides at the front and the back of the shell (1) are fixedly connected with supporting plates (16), and the lower surfaces of the supporting plates (16) are fixedly connected with the upper surface of the bottom plate through spring rods (15).

3. The high efficiency ball milling apparatus of claim 2, wherein: the spring rod (15) is composed of a spring (152) and an expansion rod (151), the spring (152) is sleeved on the outer surface of the expansion rod (151), and the top ends and the bottom ends of the spring (152) and the expansion rod (151) are respectively fixedly connected with the opposite surfaces of the supporting plate (16) and the bottom plate.

4. The high efficiency ball milling apparatus of claim 2, wherein: the upper surface fixed connection of bottom plate has shock dynamo (14), the upper surface of shock dynamo (14) and the lower surface laminating of dog, and dog fixed connection is at the lower surface of casing (1), shock dynamo (14) and external control switch electric connection.

5. The high efficiency ball milling apparatus of claim 1, wherein: the outer fixed surface who goes out hopper (10) is connected with gear b (9), and gear b (9) and gear a (8) meshing, the left surface of gear a (8) and the output shaft fixed connection of motor b (7), and motor b (7) fixed connection is at the upper surface of casing (1), motor b (7) and external control switch electric connection.

6. The high efficiency ball milling apparatus of claim 1, wherein: the outer surface of the mesh bucket (19) is fixedly connected with a plurality of grinding plates (18), a filter screen c (20) is arranged below the grinding plates (18), and the outer surface of the filter screen c (20) is fixedly connected with the inner wall of the discharge hopper (10).

7. The high efficiency ball milling apparatus of claim 6, wherein: the diameter of the meshes of the filter screen c (20) is smaller than that of the meshes of the filter screen barrel (19), the diameter of the meshes of the filter screen barrel (19) is the same as that of the meshes of the filter screen b (11), and the diameter of the meshes of the filter screen b (11) is smaller than that of the meshes of the filter screen a (2).