CN211436052U - Structure-improved new energy anode and cathode material mixer - Google Patents

Abstract

The utility model discloses a new energy anode and cathode material mixer with improved structure, which comprises a main frame, the upper end part of the main frame is provided with a mixing high-speed mixer, the upper cover of the mixing high-speed mixer is provided with a powder stirring feeding barrel and an auxiliary agent feeding box, the side frame of the main frame is arranged at the feeding port of the cooling high-speed mixer and is connected with the discharge port of the mixing high-speed mixer in a butt joint way through a connecting sleeve, the upper cover of the powder stirring feeding barrel is provided with a powder feeding pipe in a screwed way, the upper end of the powder feeding pipe is connected with a powder feeding hose in a screwed way and is connected with a powder feeding pneumatic valve in, and the pneumatic valve for feeding powder is connected with the powder storage and stirring barrel in a butt joint way, the utility model has the advantages of novel design, high automation degree and continuous production, and the whole feeding and production process can reach a fully-closed vacuum state, thereby improving the dust pollution in the working environment, avoiding the pollution in the material mixing process and ensuring the production safety.

Description

Structure-improved new energy anode and cathode material mixer

Technical Field

The utility model relates to a new forms of energy technical field specifically is a construction improvement's anodal, negative electrode material of new forms of energy mixes machine.

Background

In the mixing and processing process of the new energy anode and cathode materials, a large amount of dust is generated, the inert gas protection is not generated in the production process, the dust seriously pollutes the working environment of a workshop, the inert gas protection is not generated, serious potential safety hazards exist in the production process, and the product quality cannot be guaranteed.

In the prior art, a common method for mixing new energy positive and negative electrode materials is as follows: the powder and the auxiliary agent are poured into the mixing barrel through manual feeding, and a large amount of dust pollution can be generated in the feeding process, so that the harm can be caused to the body health of field workers.

In addition, the prior art generally adopts the mode of multiple machine stations and multiple processes to realize the mixing of the new energy anode material and the new energy cathode material, and has low automation degree, low production efficiency and high labor cost.

SUMMERY OF THE UTILITY MODEL

The utility model provides a construction improvement's the positive, negative electrode material of new forms of energy mixes machine can effectively solve and to propose in the above-mentioned background art that reinforced in-process can produce a large amount of dust pollution, and this can cause harm to field work personnel's healthy, and prior art generally adopts the mode of multiple operation of multiple units to realize that the new forms of energy is just, the negative electrode material mixes, and degree of automation is low, production efficiency is low and the problem that the cost of labor is high.

In order to achieve the above object, the utility model provides a following technical scheme: a new energy anode and cathode material mixer with an improved structure comprises a main frame, wherein a mixing high-speed mixer is arranged at the upper end part of the main frame, and a powder stirring feeding barrel and an auxiliary agent feeding box are arranged on an upper cover of the mixing high-speed mixer;

the side frame of the main frame is connected with a material inlet of the cooling high-speed mixer in a butt joint way through a connecting sleeve and a material outlet of the mixing high-speed mixer;

the upper cover of the powder stirring and feeding barrel is provided with a powder feeding pipe in a screwed manner, the upper end of the powder feeding pipe is connected with a powder feeding hose in a screwed manner and is connected with a powder feeding pneumatic valve in a screwed manner, and the powder feeding pneumatic valve is connected with the powder storage and stirring barrel in a butt joint manner;

the upper cover of the powder stirring feeding barrel is also provided with a stirring motor in a threaded manner, the stirring motor is directly connected with a powder stirring shaft, and the powder stirring shaft is driven by the stirring motor to preliminarily mix and stir the powder;

the lower end of the powder stirring and feeding barrel is provided with a powder discharging pneumatic valve in a threaded manner, the lower end of the powder discharging pneumatic valve is connected with a powder discharging hose in a threaded manner, the lower end of the powder discharging hose is connected with a powder discharging pipe in a threaded manner, and the powder discharging pipe is fixed on the upper end cover of the mixing high-speed mixer in a threaded manner;

a material pressing cylinder is screwed at the upper end of the auxiliary agent feeding box, an auxiliary agent pressing hammer is screwed at the shaft end of the material pressing cylinder, a dustproof device is arranged at an exhaust hole at the front end of the auxiliary agent pressing hammer, and a sealed front seal plate feeding high-temperature glove window is arranged right in front of the auxiliary agent feeding box;

one side of the auxiliary agent feeding box is provided with a sealing movable door plate, the upper end of the auxiliary agent feeding box is also provided with an inert gas inlet device, a gas pressure gauge, an oxygen content detector and an exhaust valve, and the auxiliary agent feeding box is connected with an auxiliary agent hopper in a screwed mode and is arranged on an upper end cover of the mixing high-speed mixer;

the upper cover of the mixing high-speed mixer can be quickly opened through the cover opening cylinder to be conveniently cleaned, the upper cover of the mixing high-speed mixer is also provided with a gas pressure gauge, an oxygen content detector and an inert gas inlet device in a threaded manner, the bottom of the mixing high-speed mixer is provided with a mixing stirring shaft end, the end face of the mixing stirring shaft is connected with a mixing high-speed cutter and a mixing high-speed cutter head, the other shaft end of the mixing stirring shaft is provided with a driven belt pulley, a mixing discharge cylinder is fixed at a discharge outlet of the mixing high-speed mixer in a threaded manner, and a mixing discharge;

the cooling high-speed mixer upper cover is also provided with a gas pressure gauge, an oxygen content detector and an inert gas inlet device in a screwed manner, the cooling high-speed mixer upper cover is provided with a connecting sleeve, the connecting sleeve is connected with the discharge port end of the mixing high-speed mixer, the bottom of the cooling high-speed mixer is provided with a cooling high-speed cutter arranged on the shaft end of the cooling stirring shaft, the other shaft end of the cooling stirring shaft is provided with a driven belt pulley in a screwed manner, the cooling high-speed mixer lower end finished product discharge port rear end is fixedly provided with a cooling discharge cylinder, and the cooling discharge cylinder shaft is provided with a cooling discharge.

Preferably, a powder storage and stirring barrel is mounted at the top end of the powder feeding pneumatic valve, and a feeding opening is formed in the upper cover of the powder stirring feeding barrel through the powder feeding pipe and the screw connection powder feeding hose in a screw installation mode;

the upper cover is provided with a stirring motor in a screwed mode to drive the direct-connected powder stirring shaft, and the powder discharging pneumatic valve, the powder discharging hose and the screwed powder discharging pipe are fixed to the upper cover feeding port of the high mixing machine in a screwed mode.

Preferably, a sealing movable door plate is arranged on one side of the auxiliary agent feeding box, and a sealed front sealing plate feeding high-temperature glove window is arranged right in front of the auxiliary agent feeding box.

Preferably, mix the high quick-witted mixing barrel that mixes and be equipped with the conduction oil outward and advance oil pipe and conduction oil play oil pipe, the conduction oil advances oil pipe and conduction oil goes out oil pipe and imports and exports continuously with high temperature mould temperature machine conduction oil, mixes the high quick-witted mixing barrel outer wall of mixing and is equipped with the temperature sensing probe, mixes the high quick-witted side and mixes main motor output shaft and go up main belt pulley and adorn on the mixed (mixing) shaft axle head of belt drive and establish passive belt pulley, passive belt pulley drives and mixes high-speed sword and mix high-speed mixing of high-speed blade disc, stirring and dispersion and reach the ideal state, mixes the high quick-witted bin outlet spiral shell of mixing and is fixed with.

Preferably, the upper end of the mixing high-speed mixer is provided with a gas pressure gauge for displaying the gas pressure in the mixing barrel of the mixing high-speed mixer.

Preferably, a driven belt pulley is arranged at one shaft end of the mixing stirring shaft of the mixing high-speed mixer, a cooling water inlet pipe and a cooling water return pipe are arranged at the shaft end of the driven belt pulley, and a cooling interlayer arranged outside a bearing seat of the mixing stirring shaft is the cooling water inlet pipe.

Preferably, the output shaft end of a cooling main motor on the side of the cooling high-speed mixer is connected with a main belt pulley, the main belt pulley is provided with a driven belt pulley on the shaft end of a belt-driven cooling stirring shaft, the driven belt pulley drives a cooling high-speed cutter to stir at a constant speed and disperse cooling materials, a cooling water interlayer cooling water inlet pipe and a cooling water return pipe are arranged outside the cooling high-speed mixer mixing barrel, and a temperature sensing probe is arranged on the outer wall of the cooling high-speed mixer mixing barrel.

Preferably, the cooling high-speed mixer is provided with a driven belt pulley at one shaft end of the cooling stirring shaft, the shaft end of the cooling stirring shaft is provided with a cooling water inlet pipe and a cooling water return pipe, and the cooling water inlet pipe and the cooling water return pipe are arranged outside the bearing seat of the cooling stirring shaft.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a new forms of energy just, negative pole material inert gas protects high machine that mixes, its main frame upper end portion installs and mixes high machine that mixes, mix high machine that mixes upper end connection powder stirring income storage bucket and auxiliary agent pan feeding case and main frame side erects the cooling high machine that mixes, it has powder stirring income storage bucket and auxiliary agent pan feeding case to lie in mixing high machine upper end cover, mix high machine bin outlet connection main frame side and erect the cooling high machine pan feeding mouth, powder stirring income storage bucket subassembly includes powder pan feeding mouth coupling assembling, powder agitator motor, powder (mixing) shaft and ejection of compact coupling assembling, auxiliary agent pan feeding case includes auxiliary agent sealed storehouse and is equipped with the pressure material cylinder on the storehouse body, inert gas air inlet, manometer and oxygen content detection instrument, it throws material gloves window and the pressure material cylinder is equipped with the auxiliary agent pressure hammer to be equipped with in the storehouse dead ahead of storehouse body, auxiliary agent pan feeding case and mixing high machine are supported, the upper cover of the mixing high-speed mixer can be quickly opened through the cover opening cylinder, when the anode material, the cathode material and the auxiliary agent enter the mixing high-speed mixer box body, the mixing main motor drives the mixing knife to be mixed at a high speed, stirred and dispersed to reach an ideal state, the mixing discharge valve is quickly opened through the mixing discharge cylinder, the mixing discharge valve enters the cooling high-speed mixer box body, the mixing discharge valve is quickly stirred at a low speed, the temperature is reduced to reach an ideal temperature, and the cooling discharge valve is quickly opened through the cooling discharge cylinder;

through the structure design, the utility model has the advantages of novel in design, degree of automation is high, serialization production, and can reach the dust pollution and the production safety guarantee in totally closed vacuum state improvement operational environment and avoid the material mixing process at whole material, the production process of throwing.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention.

In the drawings:

fig. 1 is a schematic structural diagram of the present invention;

FIG. 2 is a schematic view of the installation structure of the dustproof device of the present invention;

fig. 3 is a schematic diagram of the right-side view structure of the present invention;

fig. 4 is a schematic top view of the present invention;

fig. 5 is a schematic view of the connection structure of the present invention;

reference numbers in the figures: 1. stirring the powder into a charging basket; 11. a powder feeding pipe; 12. feeding the powder into a pneumatic valve; 13. a stirring motor; 14. feeding the powder into a hose; 15. a powder discharging pneumatic valve; 16. a powder discharge hose; 17. a powder discharge pipe; 18. a powder stirring shaft;

2. feeding an auxiliary agent into a box; 21. a material pressing cylinder; 22. a barometer; 23. an oxygen content detector; 24. an exhaust valve; 25. a movable door panel; 26. pressing hammer for auxiliary agent; 27. an inert gas inlet device; 28. an additive hopper; 29. a high temperature glove window;

3. mixing a high-speed mixer; 31. opening a cover of the cylinder; 32. mixing a high-speed cutter; 33. a mixing high-speed cutter head; 34. a mixing discharge valve; 35. a mixing stirring shaft; 36. a mixed discharging cylinder;

390. a heat conducting oil inlet pipe; 391. a heat conducting oil outlet pipe; 392. a cooling water return pipe; 393. Cooling the water inlet pipe; 39. a driven pulley; 395. a temperature sensing probe;

4. cooling the high-speed mixer; 40. cooling the high-speed cutter; 43. cooling the stirring shaft; 44. cooling the discharging cylinder; 45. a finished product discharge port; 46. cooling the discharge valve;

5. a hybrid main motor; 51. a primary pulley; 511. a belt; 261. a dust-proof device;

6. a main frame; 7. connecting sleeves; 8. a high temperature mold temperature machine; 9. cooling the main motor; 10. powder is stored in a stirring barrel; 11. a ton packaging machine; 12. a feeding fan.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Example (b): as shown in fig. 1 to 5, a new energy anode and cathode material mixer with an improved structure comprises a main frame 6, wherein a mixing high-speed mixer 3 is installed at the upper end of the main frame 6, and a powder stirring charging bucket 1 and an auxiliary agent charging box 2 are installed on the upper cover of the mixing high-speed mixer 3;

the side edge frame of the main frame 6 is connected with a material inlet of the cooling high-speed mixer 4 and a material outlet of the mixing high-speed mixer 3 in a butt joint way through a connecting sleeve 7;

a powder feeding pipe 11 is screwed on the upper cover of the powder stirring feeding barrel 1, a powder feeding hose 14 and a powder feeding pneumatic valve 12 are screwed at the upper end of the powder feeding pipe 11, and the powder feeding pneumatic valve 12 is in butt joint with the powder storage stirring barrel 10;

the upper cover of the powder stirring charging bucket 1 is also provided with a stirring motor 13 in a threaded manner, the stirring motor 13 is directly connected with a powder stirring shaft 18, and the powder stirring shaft 18 is driven by the stirring motor 13 to preliminarily mix and stir the powder;

the lower end of the powder stirring feeding barrel 1 is provided with a powder discharging pneumatic valve 15 in a threaded manner, the lower end of the powder discharging pneumatic valve 15 is connected with a powder discharging hose 16 in a threaded manner, the lower end of the powder discharging hose 16 is connected with a powder discharging pipe 17 in a threaded manner, and the powder discharging pipe 17 is fixed on the upper end cover of the mixing high-speed mixer 3 in a threaded manner;

a material pressing cylinder 21 is screwed at the upper end of the auxiliary agent feeding box 2, an auxiliary agent pressing hammer 26 is screwed at the shaft end of the material pressing cylinder 21, a dustproof device 261 is arranged at an exhaust hole at the front end of the auxiliary agent pressing hammer 26, and a sealed front sealing plate feeding high-temperature glove window 29 is arranged right in front of the auxiliary agent feeding box 2;

a sealing movable door plate 25 is arranged on one side of the auxiliary agent feeding box 2, an inert gas inlet device 27, a gas pressure gauge 22, an oxygen content detector 23 and an exhaust valve 24 are further arranged at the upper end of the auxiliary agent feeding box 2, and the auxiliary agent feeding box 2 is connected with an auxiliary agent hopper 28 in a screwed mode and is arranged on an upper end cover of the mixing high-speed mixer 3;

the upper cover of the mixing high-speed mixer 3 can be quickly opened through the cover opening cylinder 31 and is convenient to clean, the upper cover of the mixing high-speed mixer 3 is also provided with the barometer 22, the oxygen content detector 23 and the inert gas inlet device 27 in a threaded manner, the bottom of the mixing high-speed mixer 3 is provided with the axial end of a mixing stirring shaft 35, the end surface of the mixing stirring shaft 35 is connected with a mixing high-speed cutter 32 and a mixing high-speed cutter disc 33, the other axial end of the mixing stirring shaft 35 is provided with a driven belt pulley 39, the discharge port of the mixing high-speed mixer 3 is fixedly provided with a mixing discharge cylinder 36 in a threaded manner, and the;

the upper cover of the cooling high-speed mixer 4 is also provided with a barometer 22, an oxygen content detector 23 and an inert gas inlet device 27 in a threaded manner, the upper cover of the cooling high-speed mixer 4 is provided with a connecting sleeve 7, the connecting sleeve 7 is connected with the discharge port end of the mixing high-speed mixer 3 in a pipe manner, the bottom of the cooling high-speed mixer 4 is provided with a cooling high-speed cutter 40 arranged at the shaft end of the cooling stirring shaft 43, the other shaft end of the cooling stirring shaft 43 is provided with a driven belt pulley 39, the rear end of a finished product discharge port 45 at the lower end of the cooling high-speed mixer 4 is fixedly provided with a cooling discharge cylinder 44 in a threaded manner, and.

Further, a powder storage and stirring barrel 10 is mounted at the top end of the powder feeding pneumatic valve 12, and a feeding port is covered on the powder stirring feeding barrel 1 through a powder feeding pipe 11 in a screwed mode by a screw connection powder feeding hose 14;

the upper cover is provided with a stirring motor 13 in a screwed mode to drive a direct-connected powder stirring shaft 18, and a powder discharging pneumatic valve 15, a powder discharging hose 16 and a screw-connected powder discharging pipe 17 are fixed at a feeding port of the upper cover of the mixing high-speed mixer 3 in a screwed mode.

One side of the auxiliary agent feeding box 2 is provided with a sealing movable door plate 25, and a sealing front closing plate feeding high-temperature glove window 29 is arranged right in front of the auxiliary agent feeding box 2.

Further, a heat conducting oil inlet pipe 390 and a heat conducting oil outlet pipe 391 are arranged outside a mixing barrel of the mixing high-speed mixer 3, the heat conducting oil inlet pipe 390 and the heat conducting oil outlet pipe 391 are connected with a heat conducting oil inlet and outlet of a high-temperature mold temperature controller 8, a temperature sensing probe 395 is arranged on the outer wall of the mixing barrel of the mixing high-speed mixer 3, a main belt pulley 51 on the output shaft end of a main mixing motor 5 on the side of the mixing high-speed mixer 3 is provided with a driven belt pulley 39 on the shaft end of a mixing stirring shaft 35 driven by a belt 511, the driven belt pulley 39 drives a mixing high-speed knife 32 and a mixing high-speed knife disc 33 to be mixed at high speed and stirred and dispersed to reach an ideal state, a mixing discharge cylinder 36 is fixed on.

Furthermore, the upper end of the mixing high-speed mixer 3 is provided with a barometer 22 for displaying the air pressure in the mixing barrel of the mixing high-speed mixer 3.

Furthermore, a driven belt pulley 39 is arranged at one shaft end of the mixing stirring shaft 35 of the mixing high-speed mixer 3, a cooling water inlet pipe 393 and a cooling water return pipe 392 are arranged at the shaft end of the driven belt pulley 39, and a cooling interlayer serving as the cooling water inlet pipe 393 is arranged outside a bearing seat of the mixing stirring shaft 35.

Furthermore, the output shaft end of the main cooling motor 9 on the side of the cooling high-speed mixer 4 is connected with a main belt pulley 51, the main belt pulley 51 is provided with a driven belt pulley 39 at the shaft end of the belt 511 driving the cooling stirring shaft 43, the driven belt pulley 39 drives the cooling high-speed knife 40 to stir at a constant speed and disperse the cooling materials, a cooling water interlayer cooling water inlet pipe 393 and a cooling water return pipe 392 are arranged outside the mixing barrel of the cooling high-speed mixer 4, and a temperature sensing probe 395 is arranged on the outer wall of the mixing barrel of the cooling high-speed mixer 4.

Further, the cooling high-speed mixer 4 is provided with a driven pulley 39 at one axial end of the cooling stirring shaft 43, the cooling stirring shaft 43 is provided with a cooling water inlet pipe 393 and a cooling water return pipe 392 at the axial end, and the cooling stirring shaft 43 is provided with a cooling water inlet pipe 393 and a cooling water return pipe 392 outside a bearing seat.

The following description is made in detail in conjunction with a specific working process, and specifically: the packaged new energy anode and cathode powder is automatically unpacked and conveyed by a bagging machine 11 and is conveyed into a single or a plurality of powder storage and stirring barrels 10 through a feeding fan 102 to be stirred and premixed, after the powder is spirally loaded and stirred into a charging barrel 1 through a powder feeding pipe 11 and reaches a set yield through a powder feeding pneumatic valve 12 which is opened through a powder feeding pneumatic valve 12 and a lower end screw-connected powder feeding hose 14, the powder feeding pneumatic valve 12 is closed, a stirring motor 13 of the powder stirring charging barrel 1 is started to drive a direct-connected powder stirring shaft 18 to preliminarily mix and stir the powder, when an oxygen content detector 23 on a mixing high-speed mixer 3 and an auxiliary agent charging box 2 reaches a set value and the temperature of the mixing high-speed mixer 3 reaches a set temperature value through a temperature sensing probe 395, the lower end screw-connected powder discharging pneumatic valve 15 is started to convey the powder into the mixing barrel of the mixing high-speed mixer 3 through a powder discharging hose 16 and a screw-connected powder, after the powder discharging is finished, the powder discharging pneumatic valve 15 is started to close; in addition, the auxiliary agent materials which are sealed and packaged are manually put into the auxiliary agent feeding box 2 in advance, after the auxiliary agent materials which are sealed and packaged are manually put into the auxiliary agent feeding box 2, an exhaust valve 24 is opened to exhaust air in the auxiliary agent feeding box 2, an inert gas inlet device 27 is arranged at the upper end of the auxiliary agent feeding box 2, inert gas is introduced, when the digital display value of an oxygen content detector 23 at the upper end of the auxiliary agent feeding box 2 reaches a rated value, the auxiliary agent materials which are sealed and packaged are fed through a front seal plate feeding high-temperature glove window 29 arranged right in front of the auxiliary agent feeding box 2 are manually poured into an auxiliary agent hopper 28, the auxiliary agent materials are screwed into an auxiliary agent pressing hammer 26 at the shaft end of a material pressing cylinder 21 through the upper end of the auxiliary agent feeding box 2; starting a main belt pulley 51 at the output shaft end of a main mixing motor 5 on the side of a mixing high-speed mixer 3, installing a driven belt pulley 39 at the shaft end of a belt 511-driven mixing stirring shaft 35 to drive a mixing high-speed cutter 32 and a mixing high-speed cutter disc 33 to mix, stir and disperse at a high speed to reach an ideal state, starting the mixing high-speed mixer 3, fixing a mixing and discharging cylinder 36 at a discharge port of the mixing high-speed mixer by a screw, installing a mixing and discharging valve 34 at the shaft of the mixing and discharging cylinder 36, automatically opening the cooling high-speed mixer 4 connected with a discharge pipe, and automatically closing the mixing and discharging valve 34 by the mixing and discharging; a main belt pulley 51 on the output shaft end of a main cooling motor 9 on the side of a cooling high-speed mixer 4 is started, a driven belt pulley 39 is arranged on the shaft end of a cooling stirring shaft 43 driven by a belt 511 to drive a cooling high-speed knife 40 to stir at a constant speed and disperse cooled materials, and a temperature sensing probe 395 is arranged on the outer wall of a mixing barrel of the cooling high-speed mixer 4, and the cooled materials are discharged through a finished product discharge port 45 of the cooling high-speed mixer 4 after reaching a set temperature.

Synthesize the above-mentioned condition and know, through above-mentioned structural design, the utility model has the advantages of novel in design, degree of automation is high, serialization production, and can improve the dust pollution in the operational environment and the pollution of material mixing process effectively and get rid of the production potential safety hazard.

As a preferred embodiment, as shown in fig. 1 to 4, a powder feeding pneumatic valve 12 is screwed to a powder feeding hose 14 at the lower end of the upper end screw-connected powder storage and stirring barrel 10, and is screwed to a powder stirring feeding barrel 1 through a powder feeding pipe 11, the upper cover screw-connected stirring motor 13 drives a direct-connected powder stirring shaft 18 to preliminarily mix and stir the powder, and the powder feeding pneumatic valve 15 and a powder discharging hose 16 are screwed to a powder discharging pipe 17 at the lower end and is fixed to an upper cover feeding port of the mixing high-speed mixer 3 through a screw-connected powder discharging pneumatic valve 15 and a screw-connected powder discharging pipe 17, and then the powder is fed into the mixing barrel of the mixing high-speed mixer 3.

As a preferred embodiment, as shown in figures 2 and 4, a sealing movable door panel 25 is arranged on one side of the auxiliary agent feeding box 2, so that auxiliary agent materials which are conveniently and manually placed into a sealed package can be quickly opened, an exhaust valve 24 is arranged at the upper end of the auxiliary agent feeding box 2, the exhaust valve 24 is opened to discharge air in the auxiliary agent feeding box 2 after the material is manually put in, an inert gas inlet device 27 is arranged at the upper end of the auxiliary agent feeding box 2 to introduce inert gas when the digital display value of the oxygen content detector 23 at the upper end of the auxiliary agent feeding box 2 reaches the rated value, manually, a sealed front closing plate is arranged right ahead the auxiliary agent feeding box 2, the sealed and packaged auxiliary agent materials are fed into the auxiliary agent hopper 28 after being opened and sealed, the upper end of the auxiliary agent feeding box 2 is screwed on the shaft end of the material pressing cylinder 21 and is screwed with the auxiliary agent pressing hammer 26 and is pressed into the mixing barrel of the mixing high-speed mixer 3, but the upper end of the auxiliary agent feeding box 2 is provided with an air pressure gauge 22 which displays that the air pressure of the auxiliary agent feeding box 2 exceeds the designed limit exhaust valve 24 for pressure relief.

As a preferred embodiment, as shown in fig. 4, the air pressure gauge 22 is installed at the upper end of the mixing high-speed mixer 3 to indicate that the air pressure in the mixing barrel of the mixing high-speed mixer 3 exceeds the designed limit, and the air pressure is screwed into the air outlet hole at the front end of the auxiliary agent pressing hammer 26 at the shaft end of the pressing cylinder 21 which is lifted upwards to the specified position through the upper end of the auxiliary agent feeding box 2 to be decompressed, and the dust-proof device 261 is arranged at the front end of the air outlet hole at the front end of the auxiliary agent pressing hammer 26 to prevent dust from leaking into the auxiliary agent feeding.

As shown in fig. 1, as a preferred embodiment, a main belt pulley 51 is arranged on an output shaft end of a main mixing motor 5 on the side of the mixing high-speed mixer 3, a driven belt pulley 39 is arranged on the shaft end of a mixing stirring shaft 35 driven by a belt 511 to drive a mixing high-speed knife 32 and a mixing high-speed cutter disc 33 to perform high-speed mixing, stirring and dispersing to reach an ideal state, a mixing discharge cylinder 36 is fixed on a discharge port of the mixing high-speed mixer 3 in a screwed mode, and a mixing discharge valve 34 is arranged on the shaft of the mixing discharge cylinder 36 in a screwed mode to automatically open a mixing barrel of the cooling high-speed mixer.

As shown in fig. 1 and fig. 2, as a preferred embodiment, a main pulley 51 is arranged on an output shaft end of a main cooling motor 9 on the side of the cooling high-speed mixer 4, a driven pulley 39 is arranged on the shaft end of a cooling stirring shaft 43 driven by a belt 511 to drive a cooling high-speed knife 40 to stir and disperse the cooled material at a constant speed, a temperature sensing probe 395 is arranged on the outer wall of a mixing barrel of the cooling high-speed mixer 4 to a set temperature, and the cooled material is discharged through a finished product discharge port 45 of the cooling high-speed mixer 4.

In a preferred embodiment, as shown in fig. 5, the packaged new energy anode and cathode powder is automatically unpacked and transported by an bagging machine 11, and is transported by a feeding fan 102 to a single or multiple storage and stirring tanks 10 to be stirred and premixed, and is opened by a powder feeding pneumatic valve 12, and is screwed through a lower end screw-connected powder feeding hose 14 and is screwed through a powder feeding pipe 11 to be stirred with the powder in the charging tank 1.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides a structure improvement's anodal, negative pole material of new forms of energy mixes machine which characterized in that: the powder mixing and feeding device comprises a main frame (6), wherein a mixing high-speed mixer (3) is arranged at the upper end part of the main frame (6), and a powder mixing and feeding barrel (1) and an auxiliary agent feeding box (2) are arranged on the upper cover of the mixing high-speed mixer (3);

the side edge frame of the main frame (6) is connected with the material inlet of the cooling high-speed mixer (4) in a butt joint way through a connecting sleeve (7) and the material outlet of the mixing high-speed mixer (3);

a powder feeding pipe (11) is arranged on the upper cover of the powder stirring feeding barrel (1) in a screwed mode, the upper end of the powder feeding pipe (11) is connected with a powder feeding hose (14) in a screwed mode and a powder feeding pneumatic valve (12) in a screwed mode, and the powder feeding pneumatic valve (12) is connected with the powder storing and stirring barrel (10) in a butt joint mode;

the upper cover of the powder stirring feeding barrel (1) is also provided with a stirring motor (13) in a threaded manner, the stirring motor (13) is directly connected with a powder stirring shaft (18), and the powder stirring shaft (18) is driven by the stirring motor (13) to primarily mix and stir the powder;

a powder unloading pneumatic valve (15) is screwed at the lower end of the powder stirring feeding barrel (1), a powder unloading hose (16) is screwed at the lower end of the powder unloading pneumatic valve (15), a powder unloading pipe (17) is screwed at the lower end of the powder unloading hose (16), and the powder unloading pipe (17) is screwed and fixed at the upper end cover of the mixing high-speed mixer (3);

a material pressing cylinder (21) is screwed at the upper end of the auxiliary agent feeding box (2), an auxiliary agent pressing hammer (26) is screwed at the shaft end of the material pressing cylinder (21), a dustproof device (261) is arranged at an exhaust hole at the front end of the auxiliary agent pressing hammer (26), and a sealed front sealing plate feeding high-temperature glove window (29) is arranged right in front of the auxiliary agent feeding box (2);

a sealing movable door plate (25) is arranged on one side of the auxiliary agent feeding box (2), an inert gas inlet device (27), a gas pressure gauge (22), an oxygen content detector (23) and an exhaust valve (24) are further arranged at the upper end of the auxiliary agent feeding box (2), and the auxiliary agent feeding box (2) is connected with an auxiliary agent hopper (28) in a threaded manner and is arranged on an upper end cover of the mixing high-speed mixer (3);

the upper cover of the mixing high-speed mixer (3) can be quickly opened through the cover opening cylinder (31) to be conveniently cleaned, the upper cover of the mixing high-speed mixer (3) is also provided with the barometer (22), the oxygen content detector (23) and the inert gas inlet device (27) in a screwed mode, the bottom of the mixing high-speed mixer (3) is provided with a mixing stirring shaft (35) at the shaft end, the end face of the mixing stirring shaft (35) is connected with a mixing high-speed cutter (32) and a mixing high-speed cutter head (33), the other shaft end of the mixing stirring shaft (35) is provided with the driven belt pulley (39), a mixing discharge cylinder (36) is fixed at a discharge port of the mixing high-speed mixer (3) in a screwed mode, and a mixing discharge valve (;

the cooling high-speed mixer (4) upper cover is also screwed with barometer (22), oxygen content detector (23) and inert gas inlet device (27), and the cooling high-speed mixer (4) upper cover is equipped with adapter sleeve (7), and adapter sleeve (7) union coupling is in mixing high-speed mixer (3) discharge port end, and cooling high-speed mixer (4) bottom is equipped with installs on cooling (mixing) shaft (43) axle end, cooling (mixing) shaft (43) end face is connected with cooling high-speed sword (40), and cooling (mixing) shaft (43) another axle head facial make-up is equipped with passive belt pulley (39), and cooling high-speed mixer (4) lower extreme finished product bin outlet (45) rear end spiral shell is fixed with cooling row material cylinder (44), and cooling row material cylinder (44) axle spiral shell has installed cooling discharge valve (46).

2. The structure-improved new energy anode and cathode material mixing machine as claimed in claim 1, wherein a powder storage and stirring barrel (10) is installed at the top end of the powder feeding pneumatic valve (12), and a feeding port is covered on the upper cover of the powder stirring feeding barrel (1) through a powder feeding pipe (11) and a screw-connected powder feeding hose (14);

the upper cover is provided with a stirring motor (13) in a screwed manner to drive a direct-connected powder stirring shaft (18), and the powder discharging pneumatic valve (15), the powder discharging hose (16) and the screw-connected powder discharging pipe (17) are fixed at the upper cover feeding port of the mixing high-speed mixer (3) in a screwed manner.

3. The improved new energy anode and cathode material mixer as claimed in claim 1, wherein a sealing movable door panel (25) is provided at one side of the auxiliary feeding box (2), and a sealed front sealing plate feeding high temperature glove window (29) is provided right in front of the auxiliary feeding box (2).

4. The structure-improved new energy anode and cathode material mixer according to claim 1, wherein a heat conducting oil inlet pipe (390) and a heat conducting oil outlet pipe (391) are arranged outside a mixing barrel of the mixing high-speed mixer (3), the heat conducting oil inlet pipe (390) and the heat conducting oil outlet pipe (391) are connected with a heat conducting oil inlet and outlet of the high-temperature mold temperature controller (8), a temperature sensing probe (395) is arranged on the outer wall of the mixing barrel of the mixing high-speed mixer (3), a driven belt pulley (39) is arranged on an output shaft end of a main mixing motor (5) on the side of the mixing high-speed mixer (3) and is arranged at the shaft end of a mixing stirring shaft (35) driven by a belt (511), the driven belt pulley (39) drives the mixing high-speed knife (32) and the mixing high-speed knife disk (33) to be mixed, stirred and dispersed at a desired state, a mixing discharge port of the mixing high-speed mixer (3) is fixed with, the shaft of the mixing and discharging cylinder (36) is provided with a mixing and discharging valve (34).

5. The improved new energy anode and cathode material mixer as claimed in claim 1, wherein a barometer (22) is installed at the upper end of the high mixing machine (3) to display the air pressure in the mixing barrel of the high mixing machine (3).

6. The improved new energy anode and cathode material mixer as claimed in claim 1, wherein a driven pulley (39) is installed on one shaft end of the mixing stirring shaft (35) of the mixing high-speed mixer (3), a cooling water inlet pipe (393) and a cooling water return pipe (392) are installed on the shaft end of the driven pulley (39), and a cooling interlayer is installed outside a bearing seat of the mixing stirring shaft (35) and is the cooling water inlet pipe (393).

7. The structure-improved new energy anode and cathode material mixing machine as claimed in claim 1, wherein a main belt pulley (51) is connected to an output shaft end of a main cooling motor (9) on the side of the cooling high-speed mixing machine (4), a driven belt pulley (39) is arranged on the shaft end of a belt (511) driving a cooling stirring shaft (43) of the main belt pulley (51), the driven belt pulley (39) drives a cooling high-speed knife (40) to stir at a constant speed and disperse a cooling material, a cooling water interlayer cooling water inlet pipe (393) and a cooling water return pipe (392) are arranged outside a mixing barrel of the cooling high-speed mixing machine (4), and a temperature sensing probe (395) is arranged on the outer wall of the mixing barrel of the cooling high-speed mixing machine (4).

8. The improved new energy anode and cathode material mixing machine as claimed in claim 1, wherein the cooling high-speed mixing machine (4) is provided with a driven pulley (39) at one axial end of the cooling stirring shaft (43), the cooling stirring shaft (43) is provided with a cooling water inlet pipe (393) and a cooling water return pipe (392) at the axial end, and the cooling stirring shaft (43) is provided with a cooling water inlet pipe (393) and a cooling water return pipe (392) outside the bearing seat.

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