CN216728156U - Electronic ceramic screening device - Google Patents

Abstract

The utility model discloses an electronic ceramic screening device, which comprises a vibrating screen, a screen shell and a feed inlet, wherein the screen shell is arranged on the vibrating screen, the feed inlet is arranged at one end of the top surface of the screen shell, a feed hopper is arranged on the feed inlet, a flow guide buffering feed mechanism is arranged on the feed hopper, and raised dust centralized treatment structures are symmetrically arranged at two sides of the screen shell; the utility model relates to an electron ceramic machining technical field, this electron ceramic screening plant sets up the screen shell in rectilinear vibrating screen's outside to water conservancy diversion buffering feed mechanism in the feeder hopper of screen shell tip, when dredging the material, control feed rate blocks up the feed inlet simultaneously, atomize the dust fall through raise dust centralized processing structure to the air mixture when fully arousing the dust and handle, the effective separation dust, avoid rectilinear vibrating screen dust loss and remaining dust to be infected with the material scheduling problem.

Description

Electronic ceramic screening device

Technical Field

The utility model relates to an electron ceramic machining technical field specifically is an electron pottery screening plant.

Background

The electronic ceramics are ceramics that can utilize electric and magnetic properties in the electronics industry. The electronic ceramic is a ceramic with new functions finally obtained through the precise control of the surface, grain boundary and size structure. Can be widely applied to the aspects of energy sources, household appliances, automobiles and the like.

The electronic ceramic is divided into various types such as porcelain insulators, capacitor porcelain bottles and semiconductor ceramic according to function regions, in the application process of the electronic ceramic, accurate screening of materials is the basis of successful preparation in the preparation process of the electronic ceramic, the quality of screening directly determines various performances such as the smoothness and structural strength of the electronic ceramic, and the existing electronic ceramic is mainly screened by a vibrating screen in the preparation process of the electronic ceramic, but some materials in ceramic components have large dust content, and the dust impurities in the materials cannot be separated by only adopting a common screening structure.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides an electronic ceramic screening plant has solved current background technical problem.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: an electronic ceramic screening device comprises a vibrating screen, a screen shell and a feeding hole, wherein the screen shell is installed on the vibrating screen, the feeding hole is formed in one end of the top surface of the screen shell, a feeding hopper is arranged on the feeding hole, a flow guide buffering feeding mechanism is arranged on the feeding hopper, and raised dust centralized treatment structures are symmetrically arranged on two sides of the screen shell;

the water conservancy diversion buffering feed mechanism includes: the device comprises a plurality of blanking plates, a slope material guide plate and a pair of stirring rollers;

the feeding hopper is a cavity hopper body with an isosceles trapezoid cross section, a plurality of inclined blanking plates are symmetrically arranged on two sides in the feeding hopper in a staggered mode, a slope guide plate is arranged on the bottom surface of the end portion of the screen shell and connected with the vibrating screen, a pair of parallel stirring rollers is arranged on the upper portion of the slope guide plate, and the pair of stirring rollers are a pair of roller shafts annularly provided with a plurality of protruding rod-shaped bodies;

and a driving motor is arranged outside the end part of the sieve shell and is suitable for driving a pair of stirring rollers.

Preferably, the vibrating screen is an inclined linear vibrating screen with a multi-layer screen structure.

Preferably, the dust centralized processing structure comprises: a plurality of fan bases, ventilating fans, a plurality of ventilating pipes and dust falling pipes;

the screen shell is characterized in that a plurality of fan bases are linearly arranged on one side of the screen shell, the fan bases are communicated with the inside of the screen shell, ventilating fans are embedded on the fan bases, a plurality of ventilating pipes are arranged on the opposite wall surfaces of the fan bases and communicated with each other through dust falling pipes, and atomizing dust removing assemblies are arranged on the dust falling pipes.

Preferably, the inner openings of the plurality of fan bases and the plurality of vent pipes are embedded with dust screens.

Preferably, the atomizing dust-removing assembly comprises: a plurality of atomizing nozzles, a plurality of water supply pipes and a water main;

the top surface of dust fall pipe is linear array and has arranged a plurality of atomizer, and is a plurality of be connected with a plurality of delivery pipes on the atomizer, the tip of a plurality of delivery pipes passes through water main and connects.

Preferably, a plurality of vent pipes are connected with the sieve shell through a plurality of flange plates.

Advantageous effects

The utility model provides an electronic ceramic screening plant. The method has the following beneficial effects: this electronic ceramic screening plant sets up the screen shell in rectilinear vibrating screen's outside to water conservancy diversion buffering feed mechanism in the feeder hopper of screen shell tip, when dredging the material, control feed rate shutoff feed inlet simultaneously, when fully arousing the dust atomizes the dust fall through raise dust centralized processing structure to the air-fuel mixture and handles, effective separation dust, avoid rectilinear vibrating screen dust loss and surplus dust to be infected with the material scheduling problem.

Drawings

Fig. 1 is the utility model discloses an electron pottery screening plant's main structure sketch map of looking.

Fig. 2 is the utility model discloses an electronic ceramic screening plant's local front view sectional structure schematic diagram.

Fig. 3 is a schematic view of a local overlooking structure of the electronic ceramic screening device of the present invention.

In the figure: 1. vibrating screen; 2. a screen shell; 3. a feed inlet; 4. a feed hopper; 5. a blanking plate; 6. a slope material guide plate; 7. stirring the roller; 8. a drive motor; 9. a fan base; 10. a ventilating fan; 11. a breather pipe; 12. a dust settling pipe; 13. a dust screen; 14. an atomizing spray head; 15. a water supply pipe; 16. a water main; 17. a flange plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

All the electrical parts in the present case are connected with the power supply adapted to the electrical parts through a wire, and an appropriate controller and an appropriate encoder should be selected according to the actual situation to meet the control requirement, and the specific connection and control sequence should be determined.

Example (b): according to the attached figures 1-3 of the specification, the electronic ceramic screening device comprises a vibrating screen 1, a screen shell 2 and a feeding hole 3, wherein the screen shell 2 is installed on the vibrating screen 1, the feeding hole 3 is formed in one end of the top surface of the screen shell 2, a feeding hopper 4 is arranged on the feeding hole 3, a flow guide buffering feeding mechanism is arranged on the feeding hopper 4, dust centralized processing structures are symmetrically arranged on two sides of the screen shell 2, in the specific implementation process, the feeding hole 3 serves as an inlet for material loading, the material is loaded into the feeding hopper 4 and is fed into the screen shell 2 from the feeding hole 3 after being subjected to multi-stage buffering of the flow guide buffering feeding mechanism, the material is further screened through the vibrating screen 1, and the screen shell 2 is used for preventing dust from scattering around when the vibrating screen 1 vibrates;

as can be seen from the accompanying drawings 1-3 of the specification, the diversion buffer feeding mechanism comprises: a plurality of blanking plates 5, a slope material guide plate 6 and a pair of stirring rollers 7, wherein the connection relation and the position relation are as follows;

the feeding hopper 4 is a cavity hopper body with an isosceles trapezoid cross section, a plurality of inclined blanking plates 5 are symmetrically arranged on two sides in the feeding hopper 4 in a staggered mode, a slope material guide plate 6 is arranged on the bottom surface of the end portion of the screen shell 2 and connected with the vibrating screen 1, a pair of parallel stirring rollers 7 is arranged on the upper portion of the slope material guide plate 6, and the pair of stirring rollers 7 are a pair of roller shafts annularly provided with a plurality of protruding rod-shaped bodies;

in the implementation of concrete process, a plurality of flitch 5 alternate arrangement down that arrange in a staggered way on feeder hopper 4, make the material after getting into feeder hopper 4, reduce the impact force in the feeder hopper 4 that the material got into, and the speed that slows down the material and get into, improve the screening efficiency of material, on with the material is in the same direction down to shale shaker 1 through slope stock guide 6, and then stir the roller 7 through stirring of a pair of parallel to the material, thereby make adnexed dust fully arouse on the material, 2 tip of screen shell are equipped with driving motor 8 outward and are applicable to a pair of stirring roller 7 of drive, simultaneously through the structure of slope stock guide 6 as the shutoff dust, avoid the material to escape from feeder hopper 4.

As a preferable scheme, the vibrating screen 1 is an inclined linear vibrating screen 1 with a multi-layer screen structure, and the structure is simple.

As a preferable scheme, as can be seen from fig. 1 to 3 of the specification, the dust centralized processing structure includes: a plurality of fan bases 9, ventilating fans 10, a plurality of ventilating pipes 11 and dust falling pipes 12, the connection relation and the position relation of which are as follows;

a plurality of fan seats 9 are linearly arranged on one side of the screen shell 2, the fan seats 9 are communicated with the inside of the screen shell 2, ventilating fans 10 are embedded on the fan seats 9, a plurality of ventilating pipes 11 are arranged on the opposite wall surfaces of the fan seats 9, the ventilating pipes 11 are communicated through dust falling pipes 12, and atomizing dust removing components are arranged on the dust falling pipes 12;

in the specific implementation process, the ventilating fans 10 are fixed through the fan bases 9, the ventilating fans 10 generate air to be introduced into the sieve shell 2, then the air is used for bringing out dust from one side of the ventilating pipe 11 to be introduced into the dust falling pipe 12, and the mixed air is treated and discharged through the atomizing dust removing assembly.

Preferably, the inner openings of the plurality of fan seats 9 and the plurality of air pipes 11 are embedded with dust screens 13, so that materials are prevented from escaping through the fan seats 9 and the air pipes 11.

Preferably, as can be seen from fig. 1 to 3 of the specification, the atomizing dust-removing assembly includes: a plurality of atomizing nozzles 14, a plurality of water supply pipes 15, and a water main 16, which are connected in the following relationship and position;

the top surface of the dust falling pipe 12 is provided with a plurality of atomizing nozzles 14 in a linear array, the plurality of atomizing nozzles 14 are connected with a plurality of water supply pipes 15, and the end parts of the plurality of water supply pipes 15 are connected through a main water pipe 16;

in the specific implementation process, water is supplied to the water supply pipes 15 through the water headers 16, and the water is atomized through the atomizing nozzles 14, so that the dust falling treatment is performed on the mixed air.

As a preferred scheme, furthermore, a plurality of vent pipes 11 are connected with the sieve shell 2 through a plurality of flange plates 17, so that the disassembly and assembly are convenient.

To sum up the totality can know, this electronic ceramic screening plant sets up screen shell 2 in the outside of rectilinear vibrating screen 1 to water conservancy diversion buffering feed mechanism in the feeder hopper 4 of screen shell 2 tip, when dredging the material, control feed rate shutoff feed inlet 3 simultaneously atomizes the dust fall through raise dust centralized processing structure to the air mixture when fully arousing the dust and handle, effectively separate the dust, avoid 1 dust loss of rectilinear vibrating screen and remaining dust to be infected with the material scheduling problem.

It is noted that, herein, relational terms such as first and second, and the like may be 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. Also, 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. Without further limitation. The use of the phrase "comprising one of the elements does not exclude the presence of other like elements in the process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various 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 (6)

1. An electronic ceramic screening device comprises a vibrating screen (1), a screen shell (2) and a feeding hole (3), wherein the screen shell (2) is installed on the vibrating screen (1), and the feeding hole (3) is formed in one end of the top surface of the screen shell (2), and is characterized in that a feeding hopper (4) is arranged on the feeding hole (3), a flow guide buffering feeding mechanism is arranged on the feeding hopper (4), and raised dust centralized processing structures are symmetrically arranged on two sides of the screen shell (2);

the water conservancy diversion buffering feed mechanism includes: a plurality of blanking plates (5), a slope material guide plate (6) and a pair of stirring rollers (7);

the cross section of the feeding hopper (4) is an isosceles trapezoid cavity hopper body, a plurality of inclined blanking plates (5) are symmetrically arranged on two sides in the feeding hopper (4) in a staggered mode, a slope guide plate (6) is arranged on the bottom surface of the end portion of the screen shell (2) and connected with the vibrating screen (1), a pair of parallel stirring rollers (7) is arranged on the upper portion of the slope guide plate (6), and the pair of stirring rollers (7) is a pair of roller shafts which are annularly provided with a plurality of protruding rod-shaped bodies;

and a driving motor (8) is arranged outside the end part of the sieve shell (2) and is suitable for driving a pair of stirring rollers (7).

2. An electronic ceramic screening device according to claim 1, characterized in that the vibrating screen (1) is an inclined linear vibrating screen (1) of a multi-layer screen structure.

3. The electronic ceramic screening device of claim 1, wherein the dust centralized processing structure comprises: a plurality of fan bases (9), ventilating fans (10), a plurality of ventilating pipes (11) and dust falling pipes (12);

sieve shell (2) one side linear arrangement has a plurality of fan frames (9), and is a plurality of intercommunication in fan frame (9) and sieve shell (2), it is equipped with ventilating fan (10), a plurality of to inlay on fan frame (9) seted up a plurality of breather pipes (11) on the relative wall of fan frame (9), and is a plurality of breather pipe (11) are through dust fall pipe (12) intercommunication, be equipped with the dust removal subassembly of atomizing on dust fall pipe (12).

4. An electronic ceramic screening device according to claim 3, wherein the inner openings of the plurality of fan bases (9) and the plurality of air pipes (11) are embedded with dust screens (13).

5. The electroceramic screen device of claim 3, wherein the atomizing dust removal assembly comprises: a plurality of atomizing nozzles (14), a plurality of water supply pipes (15) and a water main (16);

the top surface of dust fall pipe (12) is linear array and has arranged a plurality of atomizer (14), and is a plurality of be connected with a plurality of delivery pipe (15) on atomizer (14), and the tip of a plurality of delivery pipe (15) passes through water main (16) and connects.

6. An electronic ceramic screening device according to claim 3, wherein a plurality of said air ducts (11) are connected to the screen housing (2) by a plurality of flanges (17).

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