CN117414908A - An electrode paste preparation device and its preparation method - Google Patents

Abstract

The invention discloses an electrode paste preparation device and a preparation method thereof, belonging to the technical field of electrode paste processing, and comprising a bottom plate, wherein a crushing box is fixed on the side surface of the top end of the bottom plate, a feed inlet and a discharge outlet are respectively arranged at the top end and the bottom end of the crushing box, a crushing assembly is arranged in the crushing box, a screening assembly is arranged outside the crushing box, and a vibrating assembly is arranged at one end of the screening assembly; according to the invention, the rotating screening component is used for rotationally lifting the larger particle raw materials falling into the screening component, the larger particles with unqualified fineness are poured into the top opening of the crushing box again, and the crushing component and the screening component are matched to form repeated grinding and crushing of the raw materials, so that the crushing degree is effectively improved, and the crushing effect of the raw materials is ensured; in the pivoted in-process of screening material subassembly, shake repeatedly the screening material subassembly through vibrating assembly, the efficiency of accelerating the screening material subassembly to the raw materials screening effectively reduces the jam of the sieve mesh on the screening material subassembly.

Description

Electrode paste preparation device and preparation method thereof

Technical Field

The invention belongs to the technical field of electrode paste processing, and particularly relates to an electrode paste preparation device and a preparation method thereof.

Background

The electrode paste is a conductive material for electric furnace equipment such as a ferroalloy furnace, a calcium carbide furnace and the like, can resist high temperature and has small thermal expansion coefficient. The resistor has smaller resistivity, and can reduce the loss of electric energy. The electrode has smaller porosity and can be oxidized slowly in a heating state. The electrode has higher mechanical strength, and is not broken due to the influence of mechanical and electrical loads. The electric current is fed into the furnace through the electrode to generate electric arc for smelting, the electrode occupies extremely important position in the whole electric furnace, and the electric furnace cannot generate action without the electrode. In order for the electrode to function properly at the temperatures generated by the arc, it must be highly resistant to oxidation and conductive, which is only the case for electrodes made of carbon materials. In the preparation of the electrode paste, the raw materials of the electrode paste need to be ground.

Such as Chinese patent publication No.: CN213408821U discloses a device for preparing electrode paste with uniform granularity rapidly, which comprises a base, the base top is provided with crushing chamber, crushing chamber is cuboid form, crushing chamber top is provided with the feeder hopper, the feeder hopper below is provided with grinder, grinder is including setting up grinding roller, the movable grinding roller of setting up in crushing intracavity, the relative cooperation of fixed grinding roller, movable grinding roller position is used, crushing intracavity is provided with the first filter disc of level setting up in crushing intracavity, first filter disc below is provided with the second filter disc, the discharge gate has been seted up on the crushing chamber, the discharge gate is located between first filter disc, the second filter disc, crushing chamber side is opened there is dust removal passageway, dust removal passageway end-to-end connection has the sack cleaner, sack cleaner end connection has negative pressure device. The application can rapidly prepare uniform electrode paste, and can recover the electrode paste which does not accord with the electrode paste, so that the preparation efficiency is improved.

The above-mentioned application still has the defect, and the grinding times to electrode paste raw materials is less in the above-mentioned application, and the raw materials is mingled with easily to have great granule, easily has the circumstances of smashing insufficiently, influences the raw materials crushing quality.

Therefore, there is a need for an electrode paste manufacturing apparatus and a manufacturing method thereof, which solve the problems that in the prior art, the number of grinding and crushing times of electrode paste raw materials is small, larger particles are easy to be mixed in the raw materials, insufficient crushing is easy to exist, and the crushing quality of the raw materials is affected.

Disclosure of Invention

The invention aims to provide an electrode paste preparation device and a preparation method thereof, which are used for solving the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides an electrode paste preparation facilities, includes the bottom plate, be fixed with crushing case on the top side of bottom plate, feed inlet and discharge gate have been seted up respectively to the top and the bottom of crushing case, be fixed with the support on the top side of bottom plate, be fixed with the driving motor that is located crushing case one end department on the top of support, smash the incasement and be provided with the crushing subassembly of being connected with the driving motor transmission, the outside of smashing the case is provided with the sieve material subassembly that carries out the screening with the material, be provided with vibration subassembly on the one end of sieve material subassembly.

It is to be noted in the scheme that, smash the subassembly including setting up in smashing the inside grinding roller of case, grinding roller and smashing the coaxial arrangement of case, the one end center department of grinding roller is fixed with the joint post, driving motor's output is fixed with the one end coaxial of joint post, smashing and being fixed with the bracket pole on the one end lateral wall that driving motor was kept away from to the case, the one end that smashing the case was kept away from to the bracket pole is fixed with the top side of bottom plate.

It is further worth explaining that the sieve material subassembly is including the cover locate the outside sieve feed cylinder of smashing the case, the sieve mesh has been seted up on the side of sieve feed cylinder, the sieve mesh is provided with a plurality of and a plurality of sieve meshes and is the equidistance and distribute, the sieve mesh is fixed with the one end of grinding roller, be fixed with on the inside wall of sieve feed cylinder and carry the flitch, carry the flitch and be annular distribution with a plurality of and a plurality of lifting the flitch.

It is still further to be noted that, vibration subassembly is including being fixed in the annular cover on the lateral wall of screen cylinder one end, be fixed with the arc arch on the side of annular cover, the arc arch is provided with a plurality of and a plurality of arc archs and is annular distribution, be fixed with the outer sleeve that is located annular cover under on the top side of bottom plate, sliding connection has the slide bar in the outer sleeve, be provided with the reset spring that is located the slide bar below in the outer sleeve.

As a preferred implementation mode, two symmetrically distributed convex columns are fixed on the side face of the sliding pole, and a sliding groove matched with the convex columns in a sliding mode is formed in the side face of the outer sleeve.

As a preferred embodiment, the top end of the sliding pole is provided with a cambered surface end, the side surface of the top end of the bottom plate is provided with a material containing box, and the material containing box is positioned right below the screen material cylinder.

As a preferred embodiment, a plurality of protruding blocks distributed in a ring shape are fixed on the side surface of the joint column, and a slot which is matched with the slot in a proper way is arranged on the end side surface of the screen charging barrel.

As a preferable implementation mode, a receiving hopper is fixed on the top end opening of the crushing box, and the distance between two adjacent arc-shaped bulges is larger than the diameter of the sliding column rod.

A method for preparing an electrode paste, comprising the steps of:

s1, putting a raw material to be crushed into a crushing box through an opening end of the crushing box, starting a driving motor to work, driving an output end of the driving motor to drive a joint column to rotate, driving a grinding roller to rotate in the crushing box by the joint column, and grinding and crushing the raw material in the crushing box through the rotating grinding roller;

s2, the crushed raw materials fall into a screen charging barrel through a discharge hole at the bottom of a crushing box, the crushed raw materials are screened through a plurality of screen holes on the screen charging barrel, raw material particles with qualified fineness fall out, and larger particles with unqualified fineness are continuously intercepted in the screen charging barrel;

s3, synchronously driving a screen material cylinder to rotate through a driving motor, driving a material lifting plate to rotate by the screen material cylinder, rotationally lifting the large particle raw materials falling into the screen material cylinder through the rotating material lifting plate, pouring the large particles with unqualified fineness into the top end opening of the crushing box again, pouring the large particles into the inside of the crushing box, and grinding and crushing again;

s4, in the rotating process of the screen material cylinder, the screen material cylinder drives the annular sleeve to synchronously rotate, the sliding rod is pressed to slide in the outer sleeve through the arc-shaped protrusions, and the sliding rod is reset through the reset spring, so that the sliding rod repeatedly knocks the screen material cylinder through the arc-shaped protrusions, the outer sleeve, the reset spring and the matching of the sliding rod, and the screen material cylinder is enabled to continuously vibrate.

Compared with the prior art, the electrode paste preparation device and the preparation method thereof provided by the invention at least have the following beneficial effects:

(1) The raw materials inside the crushing box are ground and crushed through the crushing assembly, the fineness of the raw materials is improved, the raw materials after grinding and crushing fall into the inside of the screen assembly through the discharge hole at the bottom of the crushing box, the crushed raw materials are screened through the screen assembly, raw material particles with qualified fineness fall out, larger particles with unqualified fineness continue to be intercepted in the inside of the screen assembly, the screen assembly is synchronously driven to rotate through the driving motor, the larger particle raw materials falling into the inside of the screen assembly are rotationally lifted through the rotating screen assembly, the larger particles with unqualified fineness are poured into the top end opening of the crushing box again and are poured into the inside of the crushing box, so that repeated grinding and crushing of the raw materials are formed through the cooperation of the crushing assembly and the screen assembly, the crushing degree is effectively improved, and the crushing effect of the raw materials is ensured.

(2) The vibration component is used for repeatedly knocking the screen material component, so that the screen material component continuously vibrates, the efficiency of screening raw materials by the screen material component is accelerated, and the blocking of screen holes on the screen material component is effectively reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of a vibration assembly according to the present invention;

FIG. 3 is a schematic elevational view of the screen assembly of the present invention;

FIG. 4 is a schematic view of a partial structure of a pulverizing assembly according to the present invention;

FIG. 5 is a schematic view of a partial structure of a screen cylinder according to the present invention;

FIG. 6 is a schematic view of a bump partial structure according to the present invention;

fig. 7 is a schematic view of a partial structure of a vibration assembly according to the present invention.

In the figure: 1. a vibration assembly; 101. an annular sleeve; 102. arc-shaped bulges; 103. a strut rod; 104. an outer sleeve; 105. a chute; 106. a convex column; 107. a return spring; 108. a cambered surface end; 2. a screening assembly; 201. a screen cylinder; 202. a sieve pore; 203. a slot; 204. a bump; 205. a lifting plate; 3. a crushing assembly; 301. a grinding roller; 302. a bracket rod; 303. a receiving hopper; 304. a connector post; 4. a crushing box; 5. a bottom plate; 6. a material-containing box; 7. a support; 8. and driving the motor.

Detailed Description

The invention is further described below with reference to examples.

Referring to fig. 1-7, the invention provides an electrode paste preparation device, which comprises a bottom plate 5, wherein a crushing box 4 is fixed on the side surface of the top end of the bottom plate 5, a feed inlet and a discharge outlet are respectively arranged at the top end and the bottom end of the crushing box 4, a support 7 is fixed on the side surface of the top end of the bottom plate 5, a driving motor 8 positioned at one end of the crushing box 4 is fixed on the top end of the support 7, a crushing assembly 3 in transmission connection with the driving motor 8 is arranged in the crushing box 4, a screening assembly 2 for screening materials is arranged outside the crushing box 4, and a vibration assembly 1 is arranged at one end of the screening assembly 2; when the grinding machine is used, raw materials to be ground are thrown into the grinding box 4 through the opening end of the grinding box 4, the driving motor 8 is started to work, the output end of the driving motor 8 drives the grinding assembly 3 to work, raw materials in the grinding box 4 are ground and ground through the grinding assembly 3, the fineness of the raw materials is improved, the ground and ground raw materials fall into the sieve assembly 2 through the discharge hole at the bottom of the grinding box 4, the ground and ground raw materials are screened through the sieve assembly 2, raw material particles with qualified fineness fall out, larger particles with unqualified fineness continue to be intercepted in the sieve assembly 2, the driving motor 8 synchronously drives the sieve assembly 2 to rotate, the larger particle raw materials falling into the sieve assembly 2 are rotated and lifted through the rotating sieve assembly 2, the unqualified larger particles are poured into the top end opening of the grinding box 4 again, the raw materials are poured into the grinding box 4, grinding is performed again through the grinding assembly 3, repeated grinding and grinding of the raw materials is formed through the cooperation of the grinding assembly 3 and the sieve assembly 2, the grinding effect of the raw materials is effectively improved; in the pivoted in-process of screening material subassembly 2, shake through vibrating subassembly 1 to screen material subassembly 2 repeatedly to make screen material subassembly 2 form and vibrate continually, accelerate the efficiency of screening material subassembly 2 to the raw materials screening, effectively reduce the jam of sieve mesh on the screen material subassembly 2.

As further shown in fig. 1, 4 and 6, it is worth specifically describing that the pulverizing assembly 3 includes a grinding roller 301 disposed inside the pulverizing box 4, the grinding roller 301 is coaxially disposed with the pulverizing box 4, a joint post 304 is fixed at a center of one end of the grinding roller 301, an output end of the driving motor 8 is coaxially fixed with one end of the joint post 304, a bracket rod 302 is fixed on an outer side wall of one end of the pulverizing box 4 far from the driving motor 8, and one end of the bracket rod 302 far from the pulverizing box 4 is fixed with a top end side of the bottom plate 5; when the grinding device is used, raw materials to be ground are thrown into the grinding box 4 through the opening end of the grinding box 4, the driving motor 8 is started to work, the output end of the driving motor 8 drives the joint post 304 to rotate, the joint post 304 drives the grinding roller 301 to rotate in the grinding box 4, the raw materials in the grinding box 4 are ground and ground through the rotating grinding roller 301, and the fineness of the raw materials is improved.

As further shown in fig. 1, 3 and 5, it is worth specifically describing that the screen material assembly 2 includes a screen material barrel 201 sleeved outside the crushing box 4, a plurality of screen holes 202 are formed in the side surface of the screen material barrel 201, the screen holes 202 are provided with a plurality of screen holes 202 which are distributed in equal intervals, the screen holes 202 are fixed with one end of the grinding roller 301, a material lifting plate 205 is fixed on the inner side wall of the screen material barrel 201, and the material lifting plate 205 is provided with a plurality of material lifting plates 205 which are distributed in a ring shape; during specific work, the raw materials after grinding and crushing fall into the screen feed cylinder 201 through the discharge hole at the bottom of the crushing box 4, the crushed raw materials are screened through the sieve holes 202 on the screen feed cylinder 201, the raw material particles with qualified fineness fall out, the larger particles with unqualified fineness continue to be intercepted in the inside of the screen feed cylinder 201, the screen feed cylinder 201 is synchronously driven to rotate through the driving motor 8, the screen feed cylinder 201 drives the lifting plate 205 to rotate, the larger particle raw materials falling into the inside of the screen feed cylinder 201 are rotationally lifted through the rotating lifting plate 205, the larger particles with unqualified fineness are poured into the top end opening of the crushing box 4 again and are poured into the inside of the crushing box 4, so that the raw materials are ground again through the crushing assembly 3, the repeated grinding and crushing of the raw materials are formed through the cooperation of the crushing assembly 3 and the screen feed assembly 2, the crushing degree is effectively improved, and the crushing effect of the raw materials is ensured.

As further shown in fig. 1, 2, 3 and 7, it should be noted that the vibration assembly 1 includes an annular sleeve 101 fixed on an outer sidewall of one end of a screen cylinder 201, an arc-shaped protrusion 102 is fixed on a side surface of the annular sleeve 101, the arc-shaped protrusion 102 is provided with a plurality of arc-shaped protrusions 102 in annular distribution, an outer sleeve 104 located right below the annular sleeve 101 is fixed on a top side surface of the bottom plate 5, a sliding rod 103 is slidably connected in the outer sleeve 104, and a return spring 107 located below the sliding rod 103 is provided in the outer sleeve 104; during specific operation, in the pivoted in-process of screen feed cylinder 201, screen feed cylinder 201 drives annular cover 101 synchronous rotation, press the smooth pole 103 through arc protruding 102 and slide in outer sleeve 104 to make smooth pole 103 reset through reset spring 107, thereby make smooth pole 103 knock screen feed cylinder 201 repeatedly through the cooperation of arc protruding 102, outer sleeve 104, reset spring 107 and smooth pole 103, thereby make screen feed cylinder 201 form continuous vibration, accelerate the efficiency of screen feed cylinder 201 to the raw materials screening, effectively reduce the jam of the sieve mesh on the screen feed cylinder 201.

The scheme comprises the following working processes: when in use, raw materials to be crushed are put into the crushing box 4 through the opening end of the crushing box 4, the driving motor 8 is started to work, the output end of the driving motor 8 drives the joint post 304 to rotate, the joint post 304 drives the grinding roller 301 to rotate in the crushing box 4, the raw materials in the crushing box 4 are ground and crushed through the rotating grinding roller 301, the ground and crushed raw materials fall into the sieve barrel 201 through the discharge hole at the bottom of the crushing box 4, the crushed raw materials are sieved through the plurality of sieve holes 202 on the sieve barrel 201, raw material particles with qualified fineness fall out, larger particles with unqualified fineness continue to be intercepted in the sieve barrel 201 and synchronously drive the sieve barrel 201 to rotate through the driving motor 8, the sieve barrel 201 drives the lifting plate 205 to rotate, the larger particle raw materials falling into the inside of the screen charging barrel 201 are rotationally lifted through the rotating lifting plate 205, the larger particles with unqualified fineness are poured into the top end opening of the crushing box 4 again, the larger particles are poured into the inside of the crushing box 4, grinding and crushing are carried out again, in the rotating process of the screen charging barrel 201, the screen charging barrel 201 drives the annular sleeve 101 to synchronously rotate, the sliding pole 103 is pressed to slide in the outer sleeve 104 through the arc-shaped protrusion 102, the sliding pole 103 is reset through the reset spring 107, and the sliding pole 103 is repeatedly knocked through the arc-shaped protrusion 102, the outer sleeve 104, the reset spring 107 and the sliding pole 103, so that the screen charging barrel 201 continuously vibrates, and the efficiency of the screening charging barrel 201 on raw materials is accelerated.

As further shown in fig. 7, it is worth specifically explaining that two symmetrically distributed convex columns 106 are fixed on the side surface of the sliding pole 103, and a sliding groove 105 which is in sliding fit with the convex columns 106 is formed on the side surface of the outer sleeve 104; when the sliding rod 103 slides in the outer sleeve 104, the sliding rod 103 drives the convex column 106 to slide in the sliding groove 105, so that the sliding of the sliding rod 103 is guided and limited, and the sliding stability of the sliding rod 103 is improved.

Further, as shown in fig. 7, it is worth specifically explaining that the top end of the sliding pole 103 is provided with a cambered surface end 108, the top end side surface of the bottom plate 5 is provided with a material containing box 6, and the material containing box 6 is positioned under the screen material cylinder 201; in specific operation, the material particles with qualified fineness screened out by the screening cylinder 201 are received through the arranged material containing box 6 and collected in a concentrated mode.

As further shown in fig. 5 and 6, it should be specifically explained that a plurality of annularly distributed protruding blocks 204 are fixed on the side surface of the joint post 304, and a slot 203 which is properly matched with the slot 203 is provided on the end side surface of the screen cylinder 201; during specific operation, the screen material cylinder 201 and the joint column 304 are fixed through the cooperation of the protruding block 204 and the inserting groove 203, so that the rotary joint column 304 drives the screen material cylinder 201 to synchronously rotate, and meanwhile, the screen material cylinder 201 is convenient to disassemble, maintain and replace.

As further shown in fig. 3 and 4, it is worth specifically explaining that the top opening of the pulverizing box 4 is fixed with a receiving hopper 303, and the distance between two adjacent arc-shaped protrusions 102 is larger than the diameter of the sliding rod 103; in a specific operation, the material is conveniently fed into the crushing box 4 through the arranged material receiving hopper 303.

A method for preparing an electrode paste, comprising the steps of:

s1, putting raw materials to be crushed into a crushing box 4 through an opening end of the crushing box 4, starting a driving motor 8 to work, driving an output end of the driving motor 8 to drive a joint post 304 to rotate, driving a grinding roller 301 to rotate in the crushing box 4 by the joint post 304, and grinding and crushing the raw materials in the crushing box 4 through the rotating grinding roller 301;

s2, the crushed raw materials fall into a screen charging barrel 201 through a discharge hole at the bottom of a crushing box 4, the crushed raw materials are screened through a plurality of screen holes 202 on the screen charging barrel 201, raw material particles with qualified fineness fall out, and larger particles with unqualified fineness are continuously intercepted in the screen charging barrel 201;

s3, synchronously driving the screen material cylinder 201 to rotate through the driving motor 8, driving the material lifting plate 205 to rotate by the screen material cylinder 201, rotationally lifting the large particle raw materials falling into the screen material cylinder 201 through the rotating material lifting plate 205, pouring the large particles with unqualified fineness into the top end opening of the crushing box 4 again, pouring into the crushing box 4, and grinding and crushing again;

s4, in the rotation process of the screen material cylinder 201, the screen material cylinder 201 drives the annular sleeve 101 to synchronously rotate, the arc-shaped protrusion 102 presses the sliding pole 103 to slide in the outer sleeve 104, and the sliding pole 103 is reset through the reset spring 107, so that the sliding pole 103 repeatedly knocks the screen material cylinder 201 through the cooperation of the arc-shaped protrusion 102, the outer sleeve 104, the reset spring 107 and the sliding pole 103, and the screen material cylinder 201 continuously vibrates.

To sum up: the raw materials inside the crushing box 4 are ground and crushed through the crushing assembly 3, the fineness of the raw materials is improved, the crushed raw materials fall into the sieve assembly 2 through a discharge hole at the bottom of the crushing box 4, the crushed raw materials are screened through the sieve assembly 2, raw material particles with qualified fineness fall out, larger particles with unqualified fineness continue to be intercepted in the sieve assembly 2, the sieve assembly 2 is synchronously driven to rotate through the driving motor 8, the larger particle raw materials falling into the sieve assembly 2 are rotationally lifted through the rotating sieve assembly 2, the larger particles with unqualified fineness are poured into the top end opening of the crushing box 4 again and are poured into the crushing box 4, so that the raw materials are ground again through the crushing assembly 3, repeated grinding and crushing of the raw materials are formed through the cooperation of the crushing assembly 3 and the sieve assembly 2, the crushing degree is effectively improved, and the crushing effect of the raw materials is ensured; in the pivoted in-process of screening material subassembly 2, shake through vibrating subassembly 1 to screen material subassembly 2 repeatedly to make screen material subassembly 2 form and vibrate continually, accelerate the efficiency of screening material subassembly 2 to the raw materials screening, effectively reduce the jam of sieve mesh on the screen material subassembly 2.

The driving motor 8 can be purchased in the market, and the driving motor 8 is provided with a power supply, which belongs to the mature technology in the field and is fully disclosed, so that the description is not repeated.

Claims (9)

1. The utility model provides an electrode paste preparation facilities, includes bottom plate (5), its characterized in that, be fixed with crushing case (4) on the top side of bottom plate (5), feed inlet and discharge gate have been seted up respectively to the top and the bottom of crushing case (4), be fixed with support (7) on the top side of bottom plate (5), be fixed with on the top of support (7) and be located driving motor (8) of crushing case (4) one end department, be provided with in crushing case (4) with driving motor (8) transmission connection smash subassembly (3), the outside of crushing case (4) is provided with sieve material subassembly (2) that sieve the material was sieved, be provided with vibration subassembly (1) on the one end of sieve material subassembly (2).

2. The electrode paste preparation device according to claim 1, wherein the grinding assembly (3) comprises a grinding roller (301) arranged inside the grinding box (4), the grinding roller (301) and the grinding box (4) are coaxially arranged, a joint column (304) is fixed at the center of one end of the grinding roller (301), the output end of the driving motor (8) is coaxially fixed with one end of the joint column (304), a bracket rod (302) is fixed on the outer side wall of one end of the grinding box (4) far away from the driving motor (8), and one end of the bracket rod (302) far away from the grinding box (4) is fixed with the top end side surface of the bottom plate (5).

3. The electrode paste preparation device according to claim 2, wherein the screen material component (2) comprises a screen material cylinder (201) sleeved outside the crushing box (4), a plurality of screen holes (202) are formed in the side face of the screen material cylinder (201), the screen holes (202) are formed in a plurality of mode and distributed at equal intervals, the screen holes (202) are fixed with one end of the grinding roller (301), material lifting plates (205) are fixed on the inner side wall of the screen material cylinder (201), and the material lifting plates (205) are arranged in a plurality of mode and distributed in a ring mode.

4. An electrode paste preparation apparatus according to claim 3, wherein the vibration assembly (1) comprises an annular sleeve (101) fixed on the outer side wall of one end of the screen cylinder (201), arc-shaped protrusions (102) are fixed on the side surface of the annular sleeve (101), the arc-shaped protrusions (102) are provided with a plurality of arc-shaped protrusions (102) in annular distribution, an outer sleeve (104) positioned right below the annular sleeve (101) is fixed on the side surface of the top end of the bottom plate (5), a sliding rod (103) is connected in a sliding manner in the outer sleeve (104), and a reset spring (107) positioned below the sliding rod (103) is arranged in the outer sleeve (104).

5. The electrode paste preparation device according to claim 4, wherein two symmetrically distributed convex columns (106) are fixed on the side surface of the sliding rod (103), and a sliding groove (105) which is in sliding fit with the convex columns (106) is formed on the side surface of the outer sleeve (104).

6. The electrode paste manufacturing apparatus as claimed in claim 4, wherein the top end of the slide bar (103) is provided with a cambered surface end (108), a material containing box (6) is placed on the top end side surface of the bottom plate (5), and the material containing box (6) is located right below the screen cylinder (201).

7. The electrode paste manufacturing apparatus according to claim 4, wherein a plurality of protrusions 204 are fixed on the side surface of the joint post 304 in a ring shape, and a slot 203 for inserting and fitting with the slot 203 is provided on the end side surface of the screen cylinder 201.

8. An electrode paste preparation apparatus according to claim 7, wherein a receiving hopper (303) is fixed to a top end opening of the pulverizing box (4), and a distance between two adjacent arc-shaped projections (102) is larger than a diameter of the spool rod (103).

9. A method for producing an electrode paste according to any one of claims 1 to 8, comprising the steps of:

s1, putting a raw material to be crushed into a crushing box (4) through an opening end of the crushing box (4), starting a driving motor (8) to work, driving a joint column (304) to rotate by an output end of the driving motor (8), driving a grinding roller (301) to rotate in the crushing box (4) by the joint column (304), and grinding and crushing the raw material in the crushing box (4) through the rotating grinding roller (301);

s2, the crushed raw materials fall into a screen charging barrel (201) through a discharge hole at the bottom of a crushing box (4), the crushed raw materials are screened through a plurality of screen holes (202) on the screen charging barrel (201), raw material particles with qualified fineness fall out, and larger particles with unqualified fineness are continuously intercepted in the screen charging barrel (201);

s3, synchronously driving a screen charging barrel (201) to rotate through a driving motor (8), driving a lifting plate (205) to rotate by the screen charging barrel (201), rotationally lifting large particle raw materials falling into the screen charging barrel (201) through the rotating lifting plate (205), pouring large particles with unqualified fineness into the top end opening of a crushing box (4) again, pouring into the inside of the crushing box (4), and grinding and crushing again;

s4, in the rotating process of the screen material cylinder (201), the screen material cylinder (201) drives the annular sleeve (101) to synchronously rotate, the arc-shaped protrusion (102) presses the sliding rod (103) to slide in the outer sleeve (104), and the sliding rod (103) is reset through the reset spring (107), so that the sliding rod (103) repeatedly shakes the screen material cylinder (201) through the arc-shaped protrusion (102), the outer sleeve (104), the reset spring (107) and the sliding rod (103), and the screen material cylinder (201) continuously vibrates.