CN110420583B - Manufacturing equipment for negative hard carbon doped silicon-carbon composite material - Google Patents

Abstract

The invention provides a manufacturing device of a negative electrode hard carbon doped silicon carbon composite material, which comprises a supporting leg and a gas transmission pipe, wherein the surface of the supporting leg is fixedly connected with a material mixing tank, the inner bottom wall of the material mixing tank is fixedly connected with a bottom rubber bag, the surface of the bottom rubber bag is sleeved with a bottom clinging material breaking spring, the inner side wall of the material mixing tank is fixedly connected with a side wall rubber bag which is mutually communicated with the bottom rubber bag, and the manufacturing device relates to the field of battery processing. This negative pole hard carbon doping silicon carbon combined material's manufacture equipment is in the same place two extreme problems associations that appear in the material processing equipment in the battery course of working, through the mode of special structure change bottom exhaust and the mode of material recovery, the time has greatly been saved, thereby the effectual processing procedure of solving general hard carbon mixing silicon charcoal, the material is gelatineous, residual material on the agitated vessel of complicacy strikes off consuming time longer, and the gelatinous material is unfavorable for the gaseous discharge in bottom, the lower problem of machining efficiency.

Description

Manufacturing equipment for negative hard carbon doped silicon-carbon composite material

Technical Field

The invention relates to the technical field of battery processing, in particular to a manufacturing device of a negative hard carbon doped silicon-carbon composite material.

Background

Some conductive materials need to be processed and prepared in the processing process of the battery, the negative electrode material of the battery at present adopts more hard carbon materials, but the conductivity of the pure hard carbon material is not very good, certain nano-scale superconducting carbon black needs to be added to improve the conductivity of the hard carbon material, namely, silicon carbide, silicon ash which is formed by collecting and processing smoke dust escaping along with waste gas by a special collecting device in the process of smelting industrial silicon and ferrosilicon by an industrial electric furnace at high temperature, silicon has the highest capacity of up to 4200mAh/g and has a stable discharge platform similar to graphite, therefore, silicon is a good conductive material, so that the silicon carbide can be added into the hard carbon when the material is processed in the manufacturing process of the battery at present, the temperature of the silicon carbide needs to be controlled in the processing process, the mixture generally has higher concentration and is colloidal, in order to mix thoroughly even, the mixed structure is generally comparatively complicated, and need will glue the material of gluing on the equipment after the processing and scrape off, this just influences work efficiency very much, and just because its is jelly, and receive the influence of expend with heat and contract with cold, the gas that its inside contains need be taken out, but concentration is higher, if the material is more, many gases of bottom are difficult to break pressure and discharge, in the course of working of general hard carbon mixing silicon charcoal, the material is jelly, the residual material on the complicated agitated vessel scrapes off consuming time longer, and colloidal material is unfavorable for the gaseous discharge in bottom, machining efficiency is lower, so need a negative pole hard carbon doping silicon carbon combined material's manufacture equipment.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides equipment for manufacturing a cathode hard carbon doped silicon-carbon composite material, and solves the problems that in the general processing process of mixing hard carbon and silicon carbon, the material is colloidal, the scraping time of residual materials on complex stirring equipment is long, the colloidal material is not beneficial to discharging bottom gas, and the processing efficiency is low.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: a manufacturing device of a negative hard carbon doped silicon carbon composite material comprises a supporting leg and a gas transmission pipe, wherein the surface of the supporting leg is fixedly connected with a material mixing tank, the inner bottom wall of the material mixing tank is fixedly connected with a bottom rubber bag, the surface of the bottom rubber bag is sleeved with a bottom clinging material breaking spring, the inner side wall of the material mixing tank is fixedly connected with a side wall rubber bag which is mutually communicated with the bottom rubber bag, the surface of the side wall rubber bag is sleeved with a side wall clinging material breaking spring, the upper surface of the material mixing tank is fixedly connected with a supporting rod, the surface of the supporting rod is fixedly provided with a motor, an output shaft of the motor is fixedly connected with a rotating shaft through a coupler, one end of the rotating shaft penetrates through and extends to the inside of the material mixing tank, an axial surface rubber bag is sleeved on the surface of the rotating shaft, and an axial surface material breaking spring is sleeved on the surface of the axial surface rubber bag.

The surface of the rotating shaft is fixedly connected with a rotating support rod, the surface of the rotating support rod is fixedly connected with a rotating support ring, the outer surface of the rotating support ring is provided with a spiral guide groove, the surface of the side wall close to the material breaking spring is fixedly connected with a plurality of traction balls, the surface of the traction balls is fixedly connected with a movable stirring rod, one end of the movable stirring rod is hinged with an in-groove guide ball, the in-groove guide ball is clamped inside the spiral guide groove, the diameter of the in-groove guide ball is smaller than the width of the inner wall of the spiral guide groove, the surface of the in-groove guide ball is fixedly connected with a plurality of vibration blocks, the surface of the rotating support rod and the surface of the rotating support ring are both sleeved with a rotating rubber bag, the surface of the movable stirring rod is sleeved with a movable rubber bag, and the surface of the rotating rubber bag and the, the surface of the rotary rubber bag is sleeved with a connecting rubber tube, and one end of the connecting rubber tube penetrates through and extends to the inside of the movable rubber bag.

The inner wall fixedly connected with bearing of the one end of gas-supply pipe, the inner circle fixedly connected with gas blow pipe of bearing, the one end of gas blow pipe runs through pivot and axial surface rubber bag and extends to the inside of axial surface rubber bag, the gas distribution pipe has been cup jointed on the surface of gas-supply pipe, the inside of gas distribution pipe's one end running through and extending to bottom rubber bag, sealed the pad has been cup jointed on the surface of bearing, the fixed surface of material blending tank is connected with the base, the fixed surface of base installs the aspiration pump, the end of bleeding of aspiration pump has cup jointed the aspiration pipe, the one end of aspiration pipe runs through and extends to the inside of material blending tank.

Preferably, the surface of material blending tank is the round platform shape, the top diameter ratio material blending tank's bottom diameter is little for the material blending tank of material blending tank, the side of material blending tank is the slope form, the material of material blending tank is the stainless steel, and the material blending tank of slope form makes things convenient for dropping of solid broken material.

Preferably, the inner wall of the spiral guide groove is fixedly connected with a non-slip mat, and the non-slip mat is made of rubber.

Preferably, the bottom clinging material breaking spring, the side wall clinging material breaking spring, the axial surface material breaking spring and the rotary material breaking spring are made of steel wires made of spring steel.

Preferably, the traction ball is positioned at the intersection point of each mesh wire of which the side wall is attached to the material breaking spring.

Preferably, the surface of the vibration block is trapezoidal, and the surface of the vibration block is connected with the surface of the non-slip mat in a sliding mode.

Preferably, the surface of the side wall rubber bag is sleeved with a control pipe, and the surface of the control pipe is provided with a control valve.

Preferably, the surface of the material mixing tank is hinged with a sealing door, the surface of the sealing door is fixedly provided with a buckle lock, and the surface of the sealing door is fixedly connected with the surface of the material mixing tank through the buckle lock.

(III) advantageous effects

(1) When the invention is used, the motor is started, the motor drives the rotating shaft to rotate, the rotating shaft rotates the rotating support rod, the rotating support rod drives the rotating support ring to rotate, when the rotating support ring rotates, the guide ball in the groove moves in the spiral guide groove, and the vibration block on the guide ball in the groove drives the movable stirring rod to shake one by one when the guide ball in the groove rolls, the guide ball in the groove is blocked by the friction resistance of the non-slip mat and continuously ascends and descends in the spiral guide groove, so that the movable stirring rod is also driven to lift and circulate when the movable stirring rod is moved, the continuously moving movable stirring rod drives the traction ball to shake, the shaken traction ball pulls the side wall to be attached to the material breaking spring to extrude the colloidal material to be sunk into the colloidal material to continuously shake, the air pump is started, and sucks the gas in the material mixing tank through the air suction pipe, at this moment, the inside of the colloidal material is tightly pasted by the side wall to break the material spring, the movable stirring rod, the rotary support ring and the rotary support rod to break the layers in all directions, so that the pressure of bottom gas is conveniently reduced, the bottom gas is conveniently discharged, and meanwhile, the effects of conveniently breaking the layers and efficiently mixing the materials are also achieved.

(2) When the invention is used, after the mixing is finished, the material which is not adhered to the equipment is taken out firstly, then the side wall adhering material breaking spring is adhered to the side wall rubber bag, the control pipe is opened through the control valve, the low-temperature cold air is input into the air conveying pipe, the low-temperature cold air enters the inner parts of the bottom rubber bag and the side wall rubber bag through the air distributing pipe, the low-temperature cold air enters the inner parts of the shaft surface rubber bag, the rotating rubber bag and the movable rubber bag through the air blowing pipe, the low-temperature cold air enables the gelatinous material to be rapidly solidified, then the control pipe is closed through the control valve, the inflation is continued, the gas enables the bottom rubber bag, the side wall rubber bag, the shaft surface rubber bag, the rotating rubber bag and the movable rubber bag to be expanded, the solidified material is broken through the expanded bottom rubber bag, the side wall rubber bag, the shaft surface rubber bag, the rotating rubber bag and, The lateral wall pastes closely and breaks material spring, the broken material spring of axial surface and rotatory broken material spring and with the extruded thin bits of material that most brokens and drop, and massive material is convenient to be retrieved to need not to strike off the material from complicated equipment, the material of recovery that also can be thorough has improved work efficiency.

(3) According to the invention, the connecting rubber tube is arranged, so that the connecting rubber tube can transmit cold air, and the connecting rubber tube has a limiting effect on the movable stirring rod, and when the movable stirring rod continues to rotate under the actions of friction, climbing force and material resistance, the connecting rubber tube exerts elastic force for pulling back the movable stirring rod, so that the self pressure of the movable stirring rod is reduced.

(4) The invention relates to two extreme problems in material processing equipment in the battery processing process, and changes the bottom exhaust mode and the material recovery mode through a special structure, thereby greatly saving time, and effectively solving the problems that the material is colloidal, the scraping time of residual materials on complicated stirring equipment is long, the colloidal material is not beneficial to the discharge of bottom gas, and the processing efficiency is low in the common processing process of hard carbon mixed silicon carbon.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a cross-sectional view of the material mixing tank configuration of the present invention;

FIG. 3 is a top view of the axial surface rubber bladder structure of the present invention;

FIG. 4 is a cross-sectional view of the spiral guide groove structure of the present invention;

FIG. 5 is a sectional view of the structure of the movable stirring rod of the present invention;

FIG. 6 is a sectional view showing the structure of a gas pipe according to the invention.

Wherein, 1 supporting leg, 2 gas-supply pipes, 3 material blending tanks, 4 bottom rubber bags, 5 bottom close material breaking springs, 6 side wall rubber bags, 7 side wall close material breaking springs, 8 supporting rods, 9 motors, 10 rotating shafts, 11 axial surface rubber bags, 12 axial surface material breaking springs, 13 rotating supporting rods, 14 rotating supporting rings, 15 spiral guiding grooves, 16 traction balls, 17 movable stirring rods, 18 in-groove guide balls, 19 vibration blocks, 20 rotating rubber bags, 21 movable rubber bags, 22 rotating material breaking springs, 23 connecting rubber pipes, 24 bearings, 25 gas blowing pipes, 26 gas distribution pipes, 27 bases, 28 air suction pumps, 29 gas suction pipes, 30 anti-skidding pads, 31 control pipes, 32 sealing doors and 33 buckling locks.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1-6, an embodiment of the present invention provides a manufacturing apparatus of a negative electrode hard carbon-doped silicon carbon composite material, including a support leg 1 and a gas pipe 2, wherein a material mixing tank 3 is fixedly connected to a surface of the support leg 1, a surface of the material mixing tank 3 is in a circular truncated cone shape, a top diameter of the material mixing tank 3 is smaller than a bottom diameter of the material mixing tank 3, a side surface of the material mixing tank 3 is in an inclined shape, the material mixing tank 3 is made of stainless steel, a bottom rubber bag 4 is fixedly connected to an inner bottom wall of the material mixing tank 3, a bottom adhesion material breaking spring 5 is sleeved on a surface of the bottom rubber bag 4, a side wall rubber bag 6 mutually communicated with the bottom rubber bag 4 is fixedly connected to an inner side wall of the material mixing tank 3, a control pipe 31 is sleeved on a surface of the side wall rubber bag 6, a control valve is disposed on a surface of the control pipe 31, a side wall adhesion material breaking, the last fixed surface of material blending tank 3 is connected with bracing piece 8, and the fixed surface of bracing piece 8 installs motor 9, and the output shaft of motor 9 passes through shaft coupling fixedly connected with pivot 10, and the one end of pivot 10 runs through and extends to the inside of material blending tank 3, and the surface of pivot 10 has cup jointed axial plane rubber bag 11, and the surface of axial plane rubber bag 11 has cup jointed the broken material spring 12 of axial plane.

The surface of the rotating shaft 10 is fixedly connected with a rotating support rod 13, the surface of the rotating support rod 13 is fixedly connected with a rotating support ring 14, the outer surface of the rotating support ring 14 is provided with a spiral guide groove 15, the inner wall of the spiral guide groove 15 is fixedly connected with an anti-skid pad 30, the anti-skid pad 30 is made of rubber, the surface of the side wall close to the breaking spring 7 is fixedly connected with a plurality of traction balls 16, the traction balls 16 are positioned at the intersection points of the meshes of the side wall close to the breaking spring 7, the surface of the traction balls 16 is fixedly connected with a movable stirring rod 17, one end of the movable stirring rod 17 is hinged with an in-groove guide ball 18, the in-groove guide ball 18 is clamped inside the spiral guide groove 15, the diameter of the in-groove guide ball 18 is smaller than the width of the inner wall of the spiral guide groove 15, the surface of the in-groove guide ball 18 is fixedly connected with a plurality of vibration blocks 19, the surface of rotation support pole 13, rotatory support ring 14's surface has all cup jointed rotatory rubber bag 20, movable rubber bag 21 has been cup jointed on the surface of activity puddler 17, rotatory broken material spring 22 has all been cup jointed on the surface of rotatory rubber bag 20 and the surface of activity rubber bag 21, the bottom pastes closely broken material spring 5, the lateral wall pastes closely broken material spring 7, the material of the broken material spring 12 of axial plane and rotatory broken material spring 22 all includes the steel wire that the spring steel made, the connection rubber tube 23 has been cup jointed on the surface of rotatory rubber bag 20, the one end of connecting rubber tube 23 runs through and extends to the inside of activity rubber bag 21.

Inner wall fixedly connected with bearing 24 of the one end of gas-supply pipe 2, the inner circle fixedly connected with gas blow pipe 25 of bearing 24, the one end of gas blow pipe 25 runs through pivot 10 and axial plane rubber bag 11 and extends to the inside of axial plane rubber bag 11, gas distribution pipe 26 has been cup jointed on the surface of gas-supply pipe 2, the one end of gas distribution pipe 26 runs through and extends to the inside of bottom rubber bag 4, sealed pad has been cup jointed on the surface of bearing 24, the fixed surface of material blending tank 3 is connected with base 27, the fixed surface of base 27 installs aspiration pump 28, the extraction end of aspiration pump 28 has been cup jointed with aspiration tube 29, the one end of aspiration tube 29 runs through and extends to the inside of material blending tank 3, the surface of material blending tank 3 articulates there is sealing door 32, the fixed surface of sealing door 32 installs padlock 33, the surface of sealing door 32 is through padlock 33 and the fixed surface of material blending tank 3 is connected.

When the device is used, a power supply is connected, the motor 9 is started, the motor 9 drives the rotating shaft 10 to rotate, the rotating shaft 10 rotates the rotating support rod 13, the rotating support rod 13 drives the rotating support ring 14 to rotate, when the rotating support ring 14 rotates, the in-groove guide ball 18 moves in the spiral guide groove 15, the vibration block 19 on the in-groove guide ball 18 drives the movable stirring rod 17 to shake one by one when the in-groove guide ball 18 rolls, the in-groove guide ball 18 continuously climbs and descends in the spiral guide groove 15 under the resistance of the friction of the anti-skid pad 30, so that the movable stirring rod 17 is also driven to lift and circulate when the movable stirring rod 17 does not move, the continuously moving movable stirring rod 17 drives the traction ball 16 to shake, the shaken traction ball 16 drags the side wall to be attached to the breaking spring 7 to extrude the side wall to be sunk into the colloidal material to be continuously shaken, starting the air pump 28, the air pump 28 pumps the air in the material mixing tank 3 through the air pumping pipe 29, the colloidal material is mixed by the side wall clinging to the material breaking spring 7, the movable stirring rod 17, the rotary supporting ring 14 and the rotary supporting rod 13 in all-dimensional damage levels, the air is pumped out from the gap, after the mixing is completed, the material which is not clinging to the equipment is taken out firstly, then the side wall clinging to the material breaking spring 7 clings to the side wall rubber bag 6, the control pipe 31 is opened through the control valve, low-temperature cold air is input into the air conveying pipe 2, the low-temperature cold air enters into the bottom rubber bag 4 and the side wall rubber bag 6 through the air distributing pipe 26, the low-temperature cold air enters into the interiors of the axial surface rubber bag 11, the rotary rubber bag 20 and the movable rubber bag 21 through the air blowing pipe 25, the colloidal material is rapidly solidified through the low-temperature cold air, then the control pipe, and continuously inflating, wherein the gas makes the bottom rubber bag 4, the side wall rubber bag 6, the axial surface rubber bag 11, the rotary rubber bag 20 and the movable rubber bag 21 expand, the expanded bottom rubber bag 4, the side wall rubber bag 6, the axial surface rubber bag 11, the rotary rubber bag 20 and the movable rubber bag 21 break the solidified material, the bottom is tightly attached with the material breaking spring 5, the side wall is tightly attached with the material breaking spring 7, the axial surface material breaking spring 12 and the rotary material breaking spring 22 break the most broken materials, the broken materials are finely crushed and fall, and the fallen materials are collected, so that the using process of the manufacturing equipment of the whole negative electrode hard carbon doped silicon carbon composite material is completed.

Claims (8)

1. The manufacturing equipment of the cathode hard carbon doped silicon carbon composite material is characterized in that: comprises supporting legs (1) and gas pipes (2), the fixed surface of the supporting legs (1) is connected with a material mixing tank (3), the inner bottom wall of the material mixing tank (3) is fixedly connected with a bottom rubber bag (4), the surface of the bottom rubber bag (4) is sleeved with a bottom pasting material breaking spring (5), the inner side wall of the material mixing tank (3) is fixedly connected with a side wall rubber bag (6) which is mutually communicated with the bottom rubber bag (4), the surface of the side wall rubber bag (6) is sleeved with a side wall pasting material breaking spring (7), the upper surface of the material mixing tank (3) is fixedly connected with a supporting rod (8), the surface of the supporting rod (8) is fixedly provided with a motor (9), the output shaft of the motor (9) is fixedly connected with a rotating shaft (10) through a coupler, one end of the rotating shaft (10) penetrates through and extends to the inside of the material mixing tank (3), the surface of the rotating shaft (10) is sleeved with a shaft surface rubber bag (11), and the surface of the shaft surface rubber bag (11) is sleeved with a shaft surface material breaking spring (12);

the surface of the rotating shaft (10) is fixedly connected with a rotating support rod (13), the surface of the rotating support rod (13) is fixedly connected with a rotating support ring (14), the outer surface of the rotating support ring (14) is provided with a spiral guide groove (15), the side wall of the rotating support ring is tightly attached to the surface of the material breaking spring (7) and is fixedly connected with a plurality of traction balls (16), the surface of each traction ball (16) is fixedly connected with a movable stirring rod (17), one end of each movable stirring rod (17) is hinged with an in-groove guide ball (18), the in-groove guide balls (18) are clamped inside the spiral guide groove (15), the diameter of the in-groove guide balls (18) is smaller than the width of the inner wall of the spiral guide groove (15), the surface of the in-groove guide balls (18) is fixedly connected with a plurality of vibration blocks (19), and the surface of the rotating support rod (13) and the surface of the rotating support ring (, the surface of the movable stirring rod (17) is sleeved with a movable rubber bag (21), the surfaces of the rotary rubber bag (20) and the movable rubber bag (21) are both sleeved with a rotary material breaking spring (22), the surface of the rotary rubber bag (20) is sleeved with a connecting rubber pipe (23), and one end of the connecting rubber pipe (23) penetrates through and extends into the movable rubber bag (21);

inner wall fixedly connected with bearing (24) of the one end of gas-supply pipe (2), inner circle fixedly connected with gas blow pipe (25) of bearing (24), the one end of gas blow pipe (25) runs through pivot (10) and axial surface rubber bag (11) and extends to the inside of axial surface rubber bag (11), gas distribution pipe (26) have been cup jointed on the surface of gas-supply pipe (2), the one end of gas distribution pipe (26) runs through and extends to the inside of bottom rubber bag (4), the surface of bearing (24) has been cup jointed sealed the pad, the fixed surface of material blending tank (3) is connected with base (27), the fixed surface of base (27) installs aspiration pump (28), the end of bleeding of aspiration pump (28) has cup jointed aspiration tube (29), the one end of aspiration tube (29) runs through and extends to the inside of material blending tank (3).

2. The manufacturing equipment of the negative electrode hard carbon doped silicon carbon composite material according to claim 1, characterized in that: the surface of material blending tank (3) is the round platform shape, the top diameter ratio of material blending tank (3) is little than the bottom diameter of material blending tank (3), the side of material blending tank (3) is the slope form, the material of material blending tank (3) is the stainless steel.

3. The manufacturing equipment of the negative electrode hard carbon doped silicon carbon composite material according to claim 1, characterized in that: the inner wall of the spiral guide groove (15) is fixedly connected with an anti-slip pad (30), and the anti-slip pad (30) is made of rubber.

4. The manufacturing equipment of the negative electrode hard carbon doped silicon carbon composite material according to claim 1, characterized in that: the materials of the bottom clinging material breaking spring (5), the side wall clinging material breaking spring (7), the axial surface material breaking spring (12) and the rotary material breaking spring (22) comprise steel wires made of spring steel.

5. The manufacturing equipment of the negative electrode hard carbon doped silicon carbon composite material according to claim 1, characterized in that: the traction ball (16) is positioned on the intersection point of each mesh wire of which the side wall is tightly attached to the material breaking spring (7).

6. The manufacturing equipment of the negative electrode hard carbon doped silicon carbon composite material according to claim 3, characterized in that: the surface of the vibration block (19) is in a trapezoid shape, and the surface of the vibration block (19) is connected with the surface of the non-slip mat (30) in a sliding mode.

7. The manufacturing equipment of the negative electrode hard carbon doped silicon carbon composite material according to claim 1, characterized in that: the surface of the side wall rubber bag (6) is sleeved with a control pipe (31), and the surface of the control pipe (31) is provided with a control valve.

8. The manufacturing equipment of the negative electrode hard carbon doped silicon carbon composite material according to claim 1, characterized in that: the surface of material blending tank (3) articulates there is sealing door (32), the fixed surface of sealing door (32) installs padlock (33), the fixed surface of surface through padlock (33) and material blending tank (3) of sealing door (32) is connected.

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