CN115318628B

CN115318628B - Ceramic carefully chosen screening plant

Info

Publication number: CN115318628B
Application number: CN202210775506.4A
Authority: CN
Inventors: 蔡喜来; 张琳悦
Original assignee: Comrolla Co ltd
Current assignee: Comrolla Co ltd
Priority date: 2022-07-01
Filing date: 2022-07-01
Publication date: 2023-10-20
Anticipated expiration: 2042-07-01
Also published as: CN115318628A

Abstract

The application discloses a ceramic fine screening device, which comprises a collecting assembly, a screening device and a screening device, wherein the collecting assembly comprises a collecting tank, a guide piece arranged in the collecting tank and a screening plate arranged on the guide piece; a screen assembly including a filter floor disposed within the collection tank, a accumulation tank movably connected to a lower end of the collection tank, and a drain pipe disposed on a sidewall of the accumulation tank; and the discharging assembly comprises a recovery pipe arranged on the accumulation pool and a pump body arranged in the recovery pipe, when screening is performed, raw materials are conveyed through a guide piece and a screening plate and fall onto a filtering bottom plate, after screening is performed, the collection pool is lifted, the raw materials with small particles are collected in the accumulation pool, and the large particles remain in the collection pool to complete screening.

Description

Ceramic carefully chosen screening plant

Technical Field

The application relates to the technical field of ceramic screening processing, in particular to a ceramic selecting and screening device.

Background

The ceramic product has higher hardness and plasticity, and when the ceramic product is processed, the blank granulation processing is often required, and some raw materials have rated requirements on granularity, so that the corresponding sieving device is usually required to sieve the granular materials so as to meet different granularity requirements.

But current ceramic raw materials screening plant adopts continuous screening's mode more, and wherein the bulk material needs to get rid of at last through longer processing, and overall treatment efficiency is comparatively low, and also has partial screening plant to use the multistage vibrations board of slope to shake the screening, but piles up to slope one side easily in the course of the treatment, influences the screening effect, and the material keeps the slope slip whereabouts simultaneously, causes partial material not in time screening easily, influences the complete screening treatment of material, and current ceramic raw materials screening plant all has the inhomogeneous problem of unloading in many, influences the even processing of device.

Aiming at the problems, the novel design is carried out on the basis of the original ceramic raw material screening device.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present application has been made in view of the above-mentioned problems associated with the prior art ceramic beneficiation screening devices.

It is therefore an object of the present application to provide a ceramic beneficiation screening device.

In order to solve the technical problems, the application provides the following technical scheme: a ceramic fine screening device comprises a collecting assembly, a screening device and a screening device, wherein the collecting assembly comprises a collecting tank, a guide piece arranged in the collecting tank and a screening plate arranged on the guide piece; a screen assembly including a filter floor disposed within the collection tank, a accumulation tank movably connected to a lower end of the collection tank, and a drain pipe disposed on a sidewall of the accumulation tank; and a discharge assembly including a recovery pipe provided on the accumulation tank and a pump body provided in the recovery pipe.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: the guide piece comprises a center column arranged at the center position of the collecting tank, a center sleeve connected outside the center column in a rotating mode and a placing groove formed in the side wall of the center sleeve, the screening plate is placed in the placing groove, the placing groove is formed in the circumferential array of the outer wall of the center sleeve, the lower end of the center column is connected with the accumulating tank, a cylindrical hole matched with the accumulating tank is formed in the center of the collecting tank, and a scraping plate is arranged at the end portion of the screening plate.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: the filter bottom plate is provided with a plurality of screening holes, a plurality of pushing blocks are connected to the filter bottom plate in a sliding manner, pushing plates are arranged on the pushing blocks, and a driving part is arranged between the central sleeve and the collecting tank.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: the driving part comprises a driving plate rotatably connected to the upper end of the filtering bottom plate, a sleeve connected to the filtering bottom plate, an internal thread arranged in the sleeve, and an external thread arranged outside the central column and matched with the internal thread, the upper end of the sleeve extends upwards,

a driving piece is arranged between the driving plate and the pushing block.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: the driving piece comprises a vortex-shaped strip arranged on the upper surface of the driving plate and a driving strip arranged at the lower end of each pushing block, the driving strips are provided with a plurality of driving strips,

the vortex strip is spiral, and a matching groove matched with the vortex strip is arranged between the driving strip and the driving strip.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: the pushing block is rotationally connected with a first driving gear, the other side of the pushing block is provided with a connecting rod, one end of the rotating shaft extending out of the connecting rod is provided with a second driving gear, the connecting rod is rotationally connected with a third driving gear connected with the second driving gear, one end of the rotating shaft extending out of the third driving gear is provided with a sweeping plate,

and a reinforcing plate is coated outside the sweeping plate.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: the filter bottom plate is provided with a supporting rod, a matching rack matched with the first driving gear is arranged on the supporting rod, a guide bar is arranged on the rotating shaft, guide wheels are arranged at two ends of the guide bar, a long-strip groove plate is arranged on the filter bottom plate, and the guide bar is matched with the long-strip groove plate.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: be provided with a plurality of fixture blocks on the lateral wall of collecting vat, the lateral wall inside of accumulating tank be provided with a plurality of drive screw with fixture block threaded connection, every drive screw lower extreme is provided with step motor, the center post upper end is provided with sunken piece, be provided with on the cylinder hole with sunken piece complex turn-ups.

As a preferred embodiment of the ceramic beneficiation screening device of the present application, wherein: the collecting tank upper end is provided with the top cap, offer on the top cap with sunken piece complex raw materials export.

The application has the beneficial effects that: when screening is carried out, raw materials are conveyed through the guide piece and the screening plate and fall onto the filtering bottom plate, after screening is carried out, the collecting tank is lifted, the raw materials with small particles are collected into the accumulating tank, and the large particles remain in the collecting tank to finish screening.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a ceramic beneficiation screening device of the present application.

FIG. 2 is a schematic view of the structure of part A of the ceramic beneficiation screening device of the present application in FIG. 1.

FIG. 3 is a schematic diagram of the drive components of the ceramic beneficiation screening device of the present application.

FIG. 4 is a cross-sectional view of a screening cell structure of a ceramic beneficiation screening device of the present application.

FIG. 5 is a schematic view of the structure of the driving member of the ceramic beneficiation screening device of the present application.

FIG. 6 is a schematic view of the structure of the sweeping plate and the screening pool of the ceramic screening device of the present application.

Wherein, 100, the collection assembly; 101. a collecting tank; 102. a guide member; 102a, a center column; 102b, a central sleeve; 102c, a placement groove; 103. a screening plate; 200. a screen assembly; 201. a filtering bottom plate; 202. a accumulating pool; 203. a discharge pipe; 204. screening holes; 205. a pushing block; 206. a push plate; 300. a driving part; 301. a driving plate; 302. a sleeve; 303. a driving member; 303a, vortex bars; 303b, a drive block; 303c, drive bars; 303d, mating grooves; 304. a first drive gear; 305. a connecting plate; 306. a sweeping plate; 307. screening the pool; 308. an inclined plate; 401. matching with a rack; 402. a guide bar; 403. a guide wheel; 404. a long groove plate; 500. a clamping block; 501. driving a screw rod; 502. a stepping motor; 503. and a raw material outlet.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

Example 1

Referring to fig. 1, a ceramic beneficiation screening device comprises, a collection assembly 100 comprising a collection basin 101, a guide 102 disposed within the collection basin 101, and a screening plate 103 disposed on the guide 102; a screen assembly 200 comprising a filter floor 201 disposed within the collection tank 101, a accumulation tank 202 movably connected to the lower end of the collection tank 101, and a discharge pipe 203 disposed on the side wall of the accumulation tank 202; and a discharge assembly connected outside the discharge pipe 203.

Specifically, the main structure of the application comprises a collecting assembly 100, in this embodiment, the collecting assembly 100 comprises a collecting tank 101, a guide member 102 is further arranged in the collecting tank 101, the guide member 102 comprises a guide pipe for conveying raw materials and guiding the discharge of the raw materials, and then a screening plate 103 is arranged on the guide member 102.

Further, the assembly of the present application further comprises a screening assembly 200. In this embodiment, the screening assembly 200 comprises a filtering bottom plate 201 disposed in the collecting tank 101, the filtering bottom plate 201 is a bottom plate of the collecting tank 101, a accumulating tank 202 is further disposed at a lower end of the collecting tank 101, the accumulating tank 202 is larger than the collecting tank 101 in size, the collecting tank 101 can slide relatively on the accumulating tank 202, a discharge pipe 203 is further communicated to the outside on a side wall of the accumulating tank 202, and the discharge pipe 203 can convey screened raw materials into the guide pipe again for secondary screening.

Meanwhile, the body of the present application further comprises a discharge assembly, which in this embodiment comprises a recovery tube disposed outside the discharge tube 203, and the front end of the recovery tube is provided with a pump body for forming negative pressure adsorption raw materials.

The operation process comprises the following steps: when screening is performed, the raw material is conveyed by the guide 102 and the screening plate 103 and falls onto the filter floor 201, after screening is performed, the collection tank 101 is lifted, the raw material of small particles is collected in the accumulation tank, and the large particles remain in the collection tank 101, so that screening is completed.

Example 2

Referring to fig. 1-6, this embodiment differs from the first embodiment in that: specifically, in the present embodiment, the guide member 102 includes a center post 102a provided at the center of the collecting tank 101, the lower end of the center post 102a is connected to the center of the bottom surface of the accumulating tank 202 and is kept in a vertical state, a center sleeve 102b is rotatably connected to the outside of the center post 102a, the rotation plane of the center sleeve 102b is horizontally provided, the rotation of the center sleeve 102b is driven by a motor, and then a plurality of placement grooves 102c are provided on the outside of the stirring sleeve 302, the placement grooves 102c being provided along the length direction of the stirring sleeve 302.

Further, a plurality of screening holes 204 are formed in the filtering bottom plate 201, the screening holes 204 are formed in a plurality, the screening holes 204 are formed in an outward diverging mode along the ring shape, the filtering bottom plate 201 is in an inverted round table shape, a plurality of pushing blocks 205 are connected to the filtering bottom plate 201 in a sliding mode, one pushing block 205 corresponds to a row of screening holes 204 along the opening state of the screening holes 204, a pushing plate 206 is arranged on the front end face of the pushing block 205, and the pushing plate 206 is in an arc-shaped plate, so that ceramic raw materials can be pushed conveniently.

Further, a driving part 300 is provided between the center sleeve 102b and the collecting tank 101, in this embodiment, the driving part 300 includes a driving plate 301 rotatably connected to the upper end of the filtering bottom plate 201, the rotation plane of the driving plate 301 is horizontally disposed and above the filtering bottom plate 201, a sleeve 302 is provided on the lower surface of the driving plate 301, the sleeve 302 is disposed at the center of the driving plate 301, and the sleeve 302 is disposed outside the center column 102 a; an internal thread is formed in the sleeve 302, an external thread matched with the internal thread is formed on the outer side of the central column 102a, and when the central column 102a moves down or up gradually, the driving plate 301 rotates by utilizing the relationship between the internal thread and the external thread.

Further, the upper end of the sleeve 302 extends upwards, and a connecting ring is arranged in the collecting tank 101 and connected with the sleeve 302, the sleeve 302 is fixed by the connecting ring, and the driving plate 301 is ensured to rotate only in the horizontal direction; a driving member 303 is provided between the driving plate 301 and the pushing blocks 205, in this embodiment, the driving member 303 includes a vortex bar 303a provided on the upper surface of the driving plate 301 and a driving block 303b provided on the upper end of each pushing block 205, a driving bar 303c is provided on the upper surface of the driving block 303b, the driving bar 303c is provided in a plurality, the vortex bar 303a is spiral, and a guide rail is provided in the collecting tank 101, the guide rail extends to the driving block 303b to guide the movement of the driving block 303b, and a fitting groove 303d for fitting the vortex bar 303a is provided between the driving bar 303c and the driving bar 303 c.

Further, a first driving gear 304 is rotatably connected to the pushing block 205, a connecting rod is arranged at the other side of the pushing block 205, a second driving gear is arranged at one end of the rotating shaft extending out of the connecting rod, a third driving gear connected with the second driving gear is rotatably connected to the connecting rod, a sweeping plate 306 is arranged at one end of the rotating shaft extending out of the third driving gear, and a reinforcing plate is coated outside the sweeping plate 306; meanwhile, a supporting rod is arranged on the filtering bottom plate 201, a matching rack 401 matched with the first driving gear 304 is arranged on the supporting rod, a guide bar 402 is arranged on the rotating shaft, guide wheels 403 are arranged at two ends of the guide bar 402, a long-strip groove plate 404 is arranged on the filtering bottom plate 201, the guide bar 402 is matched with the long-strip groove plate 404, and an included angle of 45 degrees is formed between the length direction of the guide bar 402 and the length direction of the sweeping plate 306.

The rest of the structure is the same as in embodiment 1.

The operation process comprises the following steps: when the cleaning process is performed, an operator lifts the collecting tank 101 upwards, the collecting tank 101 moves upwards, moves downwards relative to the central column 102a, so that external threads on the central column 102a drive the sleeve 302 to rotate, then the driving plate 301 rotates, after the driving plate 301 rotates, the vortex-shaped strips 303a drive the driving plate 301 to move, the driving plate 301 moves in a direction away from or close to each other, and then the pushing block 205 is driven to move, after the pushing block 205 moves, ceramic raw materials are pushed, small particles fall from the screening holes 204 and fall into the accumulating tank, and large particles enter the central sleeve 102b through the placing groove 102c and fall to the upper end of the central column 102 a; meanwhile, the pushing block 205 moves to drive the first driving gear 304 to move, when the first driving gear 304 moves to the position matched with the rack 401, the first driving gear 304 is driven to rotate, then the sweeping plate 306 is rotated by the aid of the rotating shaft, the second driving gear and the third driving gear, after that, when the collecting tank 101 moves downwards, the pushing block 205 is enabled to move reversely, the sweeping plate 306 is enabled to rotate to the vertical position, at the moment, the first driving gear 304 is separated from the rack 401, the guide bar 402 is enabled to enter the long-strip groove plate 404, the sweeping plate 306 is in the vertical state, and raw materials are sent into a negative pressure pipeline to be screened for the second time.

Example 3

Referring to fig. 1-6, this embodiment differs from the first embodiment in that: the filter bottom plate 201 is connected with a plurality of clearance boards in a sliding manner, clearance board upper end and screening board 103 butt are provided with a plurality of clearance strips on the clearance board, a plurality of rectangular grooves with clearance strip complex are offered on the filter bottom plate 201, be provided with a plurality of fixture blocks 500 on the lateral wall of collecting vat 101, the lateral wall of accumulating tank 202 is inside to be provided with a plurality of drive screw 501 with fixture block 500 threaded connection, every drive screw 501 lower extreme is provided with step motor 502, center post 102a upper end is provided with sunken piece, be provided with on the cylinder hole with sunken piece complex turn-ups, collecting vat 101 upper end is provided with the top cap, seted up on the top cap with sunken piece complex raw materials export 503.

Specifically, still slide and be connected with a plurality of clearance boards on filtering bottom plate 201, can with the screening board 103 lower extreme butt after stretching out in the upper end of clearance board, then still be provided with a plurality of clearance strips on the clearance board, the clearance strip stretches out along the face of clearance board, then set up a plurality of and clearance strip complex rectangular groove on filtering bottom plate 201, rectangular groove also can play filterable effect simultaneously.

Further, a plurality of clamping blocks 500 are arranged on the side wall of the collecting tank 101, a plurality of driving screws 501 which are in threaded connection with the clamping blocks 500 are arranged in the side wall of the accumulating tank 202, a stepping motor 502 is arranged at the lower end of each driving screw 501, a concave block is arranged at the upper end of the central column 102a, a flanging matched with the concave block is arranged on the cylindrical hole, a top cover is arranged at the upper end of the collecting tank 101, and a raw material outlet 503 matched with the concave block is formed in the top cover.

The rest of the structure is the same as in embodiment 2.

The operation process comprises the following steps: the operator makes the whole collecting tank 101 rise through driving the stepping motor 502, then the center column 102a also moves downwards relative to the collecting tank 101 at this moment, and after the collecting tank 101 rises, the position of the concave block at the upper end of the center column 102a just reaches the lowest end of the collecting tank 101, at this moment, the raw material can fall onto the concave block, then the stepping motor 502 is driven again, so that the collecting tank 101 descends, at this moment, the concave block drives the raw material to rise, and the operator can take out the raw material from the raw material outlet 503.

Claims

1. A ceramic beneficiation screening device, which is characterized in that: comprising the steps of (a) a step of,

a collection assembly (100) comprising a collection tank (101), a guide (102) disposed within the collection tank (101), and a receiving slot disposed on the guide (102);

a screening assembly (200) comprising a filter bottom plate (201) disposed within the collection tank (101), a accumulation tank (202) movably connected to the lower end of the collection tank (101), and a discharge pipe (203) disposed on the side wall of the accumulation tank (202); the method comprises the steps of,

the discharge assembly comprises a recovery pipe arranged on the accumulation pool (202) and a pump body arranged in the recovery pipe, the guide piece (102) comprises a central column (102 a) arranged at the central position of the collection pool (101), a central sleeve (102 b) rotationally connected with the outside of the central column (102 a) and a placing groove (102 c) arranged on the side wall of the central sleeve (102 b), the placing groove (102 c) is arranged along the peripheral array of the outer wall of the central sleeve (102 b), the lower end of the central column (102 a) is connected with the accumulation pool (202), a cylindrical hole matched with the accumulation pool (202) is arranged at the center of the collection pool (101),

wherein the end part of the filtering bottom plate (201) is provided with a scraping plate, a plurality of screening holes (204) are formed in the filtering bottom plate (201), a plurality of pushing blocks (205) are connected to the filtering bottom plate (201) in a sliding manner, pushing plates (206) are arranged on the pushing blocks (205), a driving part (300) is arranged between the central sleeve (102 b) and the collecting tank (101), the driving part (300) comprises a sleeve (302) rotationally connected to the filtering bottom plate (201), internal threads formed in the sleeve (302) and external threads matched with the internal threads are formed in the outer part of the central column (102 a), a driving plate (301) extends upwards from the upper end of the sleeve (302),

a driving piece (303) is arranged between the driving plate (301) and the pushing blocks (205), the driving piece (303) comprises a vortex-shaped strip (303 a) arranged on the lower surface of the driving plate (301) and a driving block (303 b) arranged at the upper end of each pushing block (205), driving strips (303 c) matched with the vortex-shaped strips (303 a) are arranged on the driving blocks (303 b), a plurality of driving strips (303 c) are arranged,

the vortex strip (303 a) is spiral, and a matching groove (303 d) matched with the vortex strip (303 a) is arranged between the driving strip (303 c) and the driving strip (303 c).

2. The ceramic beneficiation screening device of claim 1, wherein: a first driving gear (304) is rotationally connected on the pushing block (205), a connecting plate (305) is arranged on the other side of the pushing block (205), a sweeping plate (306) is arranged at one end of the rotating shaft extending out of the connecting plate (305), a screening pool (307) is arranged on one side of the accumulation pool (202), an inclined plate (308) is arranged between the screening pool (307) and the accumulation pool (202),

the sweeping plate (306) is externally covered with a reinforcing plate.

3. The ceramic beneficiation screening device of claim 1, wherein: the novel filter is characterized in that a supporting rod is arranged on the filter base plate (201), a matching rack (401) matched with the first driving gear (304) is arranged on the supporting rod, a guide bar (402) is arranged on the rotating shaft, guide wheels (403) are arranged at two ends of the guide bar (402), a long-strip groove plate (404) is arranged on the filter base plate (201), and the guide bar (402) is matched with the long-strip groove plate (404).

4. The ceramic beneficiation screening device of claim 1, wherein: be provided with a plurality of fixture blocks (500) on the lateral wall of collecting vat (101), the lateral wall inside of accumulating tank (202) is provided with a plurality of drive lead screw (501) with fixture block (500) threaded connection, every drive lead screw (501) lower extreme is provided with step motor (502), center post (102 a) upper end is provided with sunken piece, be provided with on the cylinder hole with sunken piece complex turn-ups.

5. The ceramic beneficiation screening device of claim 4, wherein: the upper end of the collecting tank (101) is provided with a top cover, and a raw material outlet (503) matched with the concave block is formed in the top cover.