CN111804426A - Mica deironing knockout drum - Google Patents

Abstract

The invention discloses a mica iron removal separation tank which comprises a tank body and a mica iron removal separation tank with a primary iron removal assembly, wherein an air outlet of the tank body is connected with an air pump, the air pump pumps air to generate negative pressure in the tank body so as to pump mica fragments into the tank body from a feed inlet and fall into the tank bottom, and air with iron is pumped out from the air outlet under the attraction of a disc magnet or is attracted onto the disc magnet. The disc magnet rotates at a low speed under the driving of the motor, and the row brushes sweep iron-containing impurities on the surface of the disc magnet into the box body, so that the separation and collection of the iron-containing impurities are realized, and the purity of mica fragments is improved.

Description

Mica deironing knockout drum

Technical Field

The invention relates to the field of mica processing, in particular to a mica iron removal separation tank.

Background

The mica powder is a non-metallic mineral and contains a plurality of components, wherein the main component is SiO2, the content is generally about 49%, and the content of Al2O3 is about 30%. The mica powder has good elasticity and toughness. The additive has the characteristics of insulativity, high temperature resistance, acid and alkali resistance, corrosion resistance, strong adhesive force and the like, and is an excellent additive. It is widely used in the industries of electric appliances, welding electrodes, rubber, plastics, paper making, paint, coating, pigment, ceramics, cosmetics, novel building materials and the like, and has extremely wide application. With the continuous development of science and technology, people open up a new application field.

In the course of working at mica powder, generally include following flow, put into the cleaning machine with the mica piece and wash with water in order to remove the impurity on the mica, then carry out centrifugal dehydration in the cleaning machine, grind the processing and form the slurry in grinding the machine after that, dry and select separately the mica powder that will grind at last and form the mica powder, the mica piece after the dehydration still generally contains impurity, among the prior art, still can't carry out the deironing to the cloud piece, is unfavorable for the purification of mica powder.

Disclosure of Invention

The invention provides a mica iron removal separation tank which can solve the problem that the prior equipment can not carry out iron removal and purification on mica fragments.

The technical scheme of the invention is that the mica iron removal separation tank comprises a tank body and a primary iron removal assembly arranged on the tank body;

the top of the tank body is provided with an opening, the opening extends inwards to form a first flanging, the tank body also comprises a feed inlet arranged at one position of the middle area of the side wall of the tank body, a discharge outlet arranged at the bottom of the tank body and an air outlet arranged at one position of the side wall of the tank body close to the top, the feed inlet and the air outlet are arranged oppositely,

the one-level deironing subassembly includes:

the cover body is arranged at the opening and is fixedly arranged on the first turned edge;

the disc magnet is arranged below the cover body and is rotationally connected with the cover body;

the first motor is arranged at the top of the cover body, is connected with the disc magnet and is used for driving the magnet to rotate;

the box body is fixedly arranged on the cover body and is positioned below the magnet;

and the row brush is arranged in the box body, and the brush bristles are in contact with the lower surface of the disc magnet and used for cleaning the surface of the magnet.

Preferably, the lateral wall of the jar body still is provided with the bar hole, mica deironing knockout drum still includes second grade deironing subassembly, second grade deironing subassembly includes:

the groove body is arranged at the strip-shaped hole, and the lower end of the groove body is provided with a collecting port;

the collecting box is arranged corresponding to the collecting opening and is detachably connected with the groove body;

the cylindrical magnet is arranged in the groove body and is rotationally connected with two ends of the groove body;

the second motor is arranged at one end of the groove body and used for driving the cylindrical magnet to rotate;

and the cleaning strip is arranged on the inner wall of the groove body, is in contact with the surface of the cylindrical magnet and is used for cleaning the cylindrical magnet.

Preferably, the cleaning strip is a felt strip, and the felt strip is obliquely arranged downwards from the inner wall of the groove body.

Preferably, the first-stage iron removal assembly further comprises a bar magnet arranged at the center of the disc magnet, and the bar magnet extends downwards from the lower surface of the disc magnet.

Preferably, the lower part of the tank body is closed to form an inverted conical surface, the discharge port is arranged at the bottom of the inverted conical surface, and the inner wall of the inverted conical surface is provided with a rubidium iron boron magnet.

Preferably, a discharge door is arranged at the discharge port.

Preferably, mica deironing knockout drum still include with the dust removal jar that the air outlet intercommunication set up, the inside of dust removal jar is provided with dust removal baffle, the top of dust removal jar is provided with the air-out pipeline.

The mica iron removal separation tank comprises a tank body and a primary iron removal assembly, an air outlet of the tank body is connected with an air pump, the air pump pumps air to generate negative pressure in the tank body so as to pump mica fragments into the tank body from a feed inlet and fall into the bottom of the tank, and air with iron is pumped out from the air outlet under the attraction of a disc magnet or is attracted onto the disc magnet. The disc magnet rotates at a low speed under the driving of the motor, and the row brushes sweep iron-containing impurities on the surface of the disc magnet into the box body, so that the separation and collection of the iron-containing impurities are realized, and the purity of mica fragments is improved.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of a mica iron removal separation tank;

FIG. 2 is a schematic structural diagram of the tank in the embodiment of FIG. 1;

FIG. 3 is a schematic structural diagram of a first-stage iron removal assembly in the embodiment of FIG. 1;

FIG. 4 is a schematic structural diagram of a secondary iron removal assembly in the embodiment of FIG. 1;

fig. 5 is a schematic structural diagram of another view of the secondary iron removal assembly in the embodiment of fig. 1.

Detailed Description

The invention provides a mica iron removal separation tank, which comprises a tank body 12 and a primary iron removal assembly 14 arranged on the tank body 12, and is shown in figures 1 to 5. In this embodiment, the mica deironing separation tank is disposed on a frame 10a, and wheels 10b are disposed on both sides of the frame 10 a. The top opening of the tank body 12 is arranged, the opening extends inwards to form a first flanging, the tank body 12 further comprises a feed inlet 12a arranged at one position of the middle area of the side wall of the tank body, a discharge outlet 12b arranged at the bottom of the tank body 12 and an air outlet 12d arranged at one position of the side wall of the tank body close to the top, the feed inlet 12a and the air outlet 12d are arranged oppositely, and a feed pipe 11 is arranged at the position of the feed inlet 12 a.

In this embodiment, the primary iron removing assembly 14 includes a cover 14a, a disc magnet 14b, a first motor, a case 14c, and a row brush 14 d. The cover 14a is disposed at the opening and is fixed to the first flap. The disc magnet 14b is disposed below the cover 14a, and has a center shaft 14e on the upper surface thereof, and the center shaft 14e is rotatably connected to the cover 14 a. The first motor is disposed on the top of the cover 14a, and a rotating shaft of the first motor is connected to the central shaft 14e through a gear set or a worm gear reducer (not shown in the figure) for driving the magnet to rotate, and the gear set or the worm gear reducer performs a speed reduction function to enable the disc magnet 14b to rotate at a low speed. The box 14c is fan-shaped, and has an open upper end and is fixedly disposed on the cover 14a and below the magnet. The row brush 14d is disposed in the case 14c, and the brush is in contact with the lower surface of the disc magnet 14b to clean the surface of the magnet, and when impurities are adsorbed on the surface of the disc magnet 14b, the disc magnet 14b rotates to allow the row brush 14d to clean the impurities into the case 14 c.

The mica iron removal separation tank comprises a tank body 12 and a primary iron removal assembly 14, an air outlet 12d of the tank body 12 is connected with an air pump, the air pump pumps air to enable the interior of the tank body 12 to generate negative pressure so as to pump mica fragments into the tank body 12 from a feed port 12a and fall into the bottom of the tank, and air with iron is pumped out from the air outlet 12d under the attraction of a disc magnet 14b or is attracted onto the disc magnet 14 b. The disc magnet 14b rotates at a low speed under the driving of the motor, and the row brush 14d sweeps the iron-containing impurities on the surface of the disc magnet into the box body 14c, so that the separation and collection of the iron-containing impurities are realized, and the purity of mica fragments is improved.

In this embodiment, the lateral wall of jar body 12 still is provided with bar hole 12c, mica deironing knockout drum still includes second grade deironing subassembly, second grade deironing subassembly includes cell body 15a, collection box 15e, cylindrical magnet 15c, second motor 15d and cleaning strip 15 f. The tank body 15a is arranged at the strip-shaped hole 12c, second turned-over edges 15b for fixedly connecting with the tank body 12 are arranged on two sides of the tank body 15a, and a collecting port is arranged at the lower end of the tank body 15 a; the collecting box 15e is arranged corresponding to the collecting opening and is detachably connected with the groove body 15 a. The two joint sets up in this embodiment, and collection mouth department is provided with the draw-in groove, and the upper end of collecting box 15e outwards extends and is provided with the joint strip, joint strip and draw-in groove adaptation.

In this embodiment, a cylindrical magnet 15c is disposed in the slot body 15a, and a central shaft is disposed at both ends of the cylindrical magnet 15c and extends outwards, and the central shaft is rotatably connected with both ends of the slot body 15 a. The second motor 15d is arranged at the upper end of the slot body 15a and is used for driving the cylindrical magnet 15c to rotate. The cleaning strip 15f is arranged on the inner wall of the groove body 15a, is in contact with the surface of the cylindrical magnet 15c and is used for cleaning the cylindrical magnet 15 c. In this embodiment, the cleaning strip 15f is a felt strip disposed obliquely downward from the inner wall of the tank body 15 a. During the rotation of the cylindrical magnet 15c, the felt strips can sweep away the impurities adsorbed thereon into the collecting box 15 e.

In this embodiment, the primary iron removing assembly 14 further includes a bar magnet (not shown) disposed at the center of the disc magnet 14b, and the bar magnet is disposed to extend downward from the lower surface of the disc magnet 14 b. Where the bar magnet is also preferably cylindrical, the mica chips enter the tank 12 and ferrous impurities are attracted by the bar magnet for further removal of iron. Further, the lower part of the tank body 12 is closed to form an inverted conical surface, the discharge port 12b is arranged at the bottom of the inverted conical surface, and the inner wall of the inverted conical surface is provided with a rubidium iron boron magnet. The mica sheets and impurities enter the tank body 12 and are firstly deironized by the disc magnet 14b, the cylindrical magnet 15c and the bar magnet, and the remaining impurities fall into the bottom of the tank body 12 and are further purified by the magnets of the rubidium, iron and boron at the bottom.

In this embodiment, a discharge gate 12e is disposed at the discharge port 12b, and after a certain amount of mica chips are collected in the tank 12, the discharge gate 12e can be opened to transfer the purified mica chips. In this embodiment, mica deironing knockout drum still include with dust removal tank 13 that air outlet 12d intercommunication set up, dust removal tank 13's inside is provided with dust removal baffle, dust removal tank 13's top is provided with air-out pipeline 13 a. Can remain other impurity that get into in the jar to the jar in through setting up dust removal jar 13, avoid along with air-out pipeline 13a entering aspiration pump, cause the damage of aspiration pump.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, however, as long as there is no contradiction between the combinations of the technical features, the scope of the present description should be considered as being described in the present specification. The above examples only show some embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention.

Claims (7)

1. A mica iron-removing separating tank is characterized by comprising a tank body and a primary iron-removing component arranged on the tank body;

the top of the tank body is provided with an opening, the opening is provided with a first flanging in an inward extending manner, the tank body also comprises a feed inlet arranged at one position of the middle area of the side wall of the tank body, a discharge outlet arranged at the bottom of the tank body and an air outlet arranged at one position of the side wall of the tank body, which is close to the top, and the feed inlet and the air outlet are arranged oppositely;

the one-level deironing subassembly includes:

the cover body is arranged at the opening and is fixedly arranged on the first turned edge;

the disc magnet is arranged below the cover body and is rotationally connected with the cover body;

the first motor is arranged at the top of the cover body, is connected with the disc magnet and is used for driving the magnet to rotate;

the box body is fixedly arranged on the cover body and is positioned below the magnet;

and the row brush is arranged in the box body, and the brush bristles are in contact with the lower surface of the disc magnet and used for cleaning the surface of the magnet.

2. The mica deironing knockout drum of claim 1, characterized in that, the lateral wall of the jar body still is provided with the bar hole, the mica deironing knockout drum still includes second grade deironing subassembly, second grade deironing subassembly includes:

the groove body is arranged at the strip-shaped hole, and the lower end of the groove body is provided with a collecting port;

the collecting box is arranged corresponding to the collecting opening and is detachably connected with the groove body;

the cylindrical magnet is arranged in the groove body and is rotationally connected with two ends of the groove body;

the second motor is arranged at one end of the groove body and used for driving the cylindrical magnet to rotate;

and the cleaning strip is arranged on the inner wall of the groove body, is in contact with the surface of the cylindrical magnet and is used for cleaning the cylindrical magnet.

3. The mica iron-removing separating tank of claim 2, wherein the cleaning strips are felt strips, and the felt strips are obliquely arranged downwards from the inner wall of the tank body.

4. The mica iron removal separation tank of claim 1, wherein the primary iron removal assembly further comprises a bar magnet disposed in the center of the disc magnet, the bar magnet extending downwardly from the lower surface of the disc magnet.

5. The mica iron-removing separating tank as claimed in claim 1, wherein the lower part of the tank body is closed to form an inverted conical surface, the discharge port is arranged at the bottom of the inverted conical surface, and the inner wall of the inverted conical surface is provided with a rubidium iron boron magnet.

6. The mica iron-removing separating tank of claim 1, wherein a discharge door is arranged at the discharge port.

7. The mica iron-removing separating tank of any one of claims 1 to 5, wherein the mica iron-removing separating tank further comprises a dust-removing tank communicated with the air outlet, a dust-removing baffle is arranged inside the dust-removing tank, and an air outlet pipeline is arranged at the top of the dust-removing tank.

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