CN112191125A - Production process and manufacturing equipment of graphite coiled material with ultralow ignition loss - Google Patents

Abstract

The invention discloses a production process and manufacturing equipment of an ultra-low ignition loss graphite coiled material, which comprises a mixer, wherein a batching component for quantitatively allocating corresponding mixed materials is connected between the mixer and a feeding bin, a scattering component for scattering and mixing the graphite materials fed in the feeding bin and the mixed materials fed in the batching component in advance is connected in the mixer, one end of the scattering component is connected with a stirring main shaft of the mixer, and the physical allocation, feeding, mixing, stirring and discharging are carried out.

Description

Production process and manufacturing equipment of graphite coiled material with ultralow ignition loss

Technical Field

The invention relates to the technical field of graphite coiled materials, in particular to a production process and manufacturing equipment of an ultra-low ignition loss graphite coiled material.

Background

The graphite heat dissipation and conduction material is a preferred material for solving the heat dissipation and conduction technology of modern electronic products due to the unique low density (relative to metals), high heat dissipation and conduction coefficient and low thermal resistance. The graphite heat sink not only can be followed horizontal heat conduction, can also be followed the vertical direction heat conduction, especially utilizes lamellar structure, not only can make its surface that is applicable to any product better, still can effectually play the effect of heat dissipation heat conduction, and the graphite coiled material has fluffy state processing to become the graphite book that has super low fever vector performance through mixing graphite worm (EG) and phosphate etc. when producing, in the graphite worm.

When the graphite coiled material is prepared by the existing equipment, the graphite raw material to be processed and the like are placed in a processing bin, the processed material is weighed, and then the corresponding phosphate, antioxidant and the like are proportioned in a quantitative manner, mixing the processed graphite raw material with corresponding phosphate and antioxidant, adding into a mixer, mixing, stirring, mixing phosphate, antioxidant and EG, because EG, antioxidant and the like are added from a charging barrel at the top of the mixer, EG is intensively dropped at the central position of the mixer, which is not beneficial to full contact of EG and antioxidant and the like, meanwhile, after the addition of the processing raw materials is finished, the feeding bin and the antioxidant adding tank are closed, the mixture is stirred for a period of time, the method has the advantages that the mixing time of EG and antioxidant is long, the EG is not beneficial to the rapid contact mixing reaction of EG and the antioxidant, and therefore, a production process and manufacturing equipment of the graphite coiled material with ultra-low ignition loss are provided.

Disclosure of Invention

The invention aims to provide production and manufacturing equipment for an ultra-low ignition loss graphite coiled material, so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides an ultralow loss of ignition graphite coiled material production manufacture equipment, includes the blendor, the blendor top is connected with the feeding storehouse, and the blendor bottom is connected with the unloading valve, blendor internal connection has the stirring main shaft, be connected with the batching subassembly of the corresponding mixed material of ration configuration between blendor and the feeding storehouse, blender internal connection has the graphite material of unloading in with the feeding storehouse and the mixed material of unloading in the batching subassembly to break in advance and scatter the subassembly of mixing, and scatter the stirring main shaft of subassembly one end and blendor and be connected, and the graphite coiled material of being convenient for is add man-hour and is broken up raw and other materials in advance.

Preferably, the batching subassembly is including setting up the batching pipe at the blendor top, batching pipe one end UNICOM has a plurality of batching jars, and batching pipe other end UNICOM has horizontal pipe, horizontal pipe both ends UNICOM has the branch pipe respectively, branch pipe bottom UNICOM has a plurality of shower nozzles, and shower nozzle one end installs inside the blendor, the branch pipe distributes in feeding storehouse bottom both sides, and is connected with star type ration blanking machine bottom the feeding storehouse, and the inside processing mixture that adds of quantitative case blendor of being convenient for.

Preferably, break up the subassembly including connecting at stirring main shaft one disconnected driving gear, driving gear top both sides are connected with two drive gear respectively, are connected with the pivot on two drive gear, and the pivot is connected with the blendor lateral wall, are connected with the rotor plate on one of them shown drive gear, and are connected with the vertical processing piece of vertically breaking up the mixture of compounding on another drive gear, be connected with spacing sliding frame on the inside both sides wall of blendor respectively, and sliding connection has the horizontal pole of breaking up between two spacing sliding frame, the pole one end of transversely breaking up is connected with the promotion subassembly, and promotes the subassembly and is connected with the rotor plate, the inside bottom of blendor is connected with the bottom and divides the material subassembly, and the material subassembly is divided with the driving gear to the bottom, is convenient for increase.

Preferably, the pushing assembly comprises an eccentric shaft connected to the rotating plate, a first crank arm is sleeved on the eccentric shaft, one end of the first crank arm is connected with a second crank arm in an intersecting mode, one end of the second crank arm is movably connected to the inside of the limiting sliding frame, one end, far away from the first crank arm, of the second crank arm is connected with one end, far away from the first crank arm, of the transverse scattering rod, and the eccentric shaft is convenient for intermittently pushing the first crank arm to move.

Preferably, the vertical processing piece comprises a crank arm rotating rod connected to the transmission gear, the other end of the crank arm rotating rod is connected with the side wall of the mixer, a plurality of hinged supports are connected to the crank arm rotating rod, one end of each hinged support is hinged to a vertical moving part which vertically breaks up the mixture, a fixed beam is arranged at the top of each vertical moving part, and two ends of each fixed beam are respectively connected to the side wall of the mixer, so that the mixture is conveniently and transversely pushed to break up.

Preferably, vertical moving part is including connecting the activity push pedal on articulated support, activity push pedal top is equipped with spacing frame, and spacing frame top and fixed beam connection, activity push pedal one end sliding connection is inside spacing frame, and activity push pedal one side is connected with the crushing pole, is favorable to the multiple spot department to carry out the top and moves and break up the mixture.

Preferably, the bottom divides the material subassembly to include the first gear of joggle connection in the driving gear outside, the meshing of driving gear outside has the second gear, and the second gear is located first gear one side, second gear one side is connected with steering gear, and all is connected with the dwang on steering gear and the first gear, dwang one end and blendor inner wall connection, the inside bottom of blendor is equipped with the branch material platform, divide the material platform to be located unloading valve top, divide the material platform top to be equipped with the material pushing component that two pushed materials relatively, and material pushing component one end is connected with the dwang, and steering gear is convenient for adjust the turning to of first gear and second gear.

Preferably, the material pushing part is arranged on the tooth socket plates on two sides of the material distributing table, two sliding blocks are connected to the tooth socket plates, two sides of the material distributing table are respectively provided with a sliding groove, the sliding blocks are connected to the sliding grooves in the positions of the sliding grooves, one side of each tooth socket plate is connected with a material pushing rod, the material pushing rods are located at the top of the material distributing table, two sides of the material distributing table are respectively connected with a roller, one end of each roller is connected with a half gear, the half gears are meshed with the tooth socket plates, one end, away from the half gears, of each roller is connected with a first helical gear, the outer side of each rotating rod is connected with a second helical gear, the first helical gears are meshed.

The production process of the graphite coiled material with ultra-low ignition loss comprises the following steps of using the manufacturing equipment to perform processing treatment:

a: physical preparation and material ratio, wherein EG: phosphoric acid: phosphate =: 100: 0.5-1.5: 1-2,

the EG preparation range is less than or equal to 800kg, the capacity of the mixing machine is less than or equal to 1000kg,

preparing an antioxidant, and calculating according to the EG amount ratio;

b: feeding, mixing and stirring, starting a star-shaped quantitative blanking machine 12 at 50-75 kg/min, and starting a mixer 1 at a stirring speed of 80-100 revolutions/min;

opening compressed air, starting a pipeline valve of the dosing tank 8, and checking whether the spraying is normal or not at the flow rate of 10 kg/min;

after the antioxidant is added, a valve is switched to open the proportioning tank 8, and the flow rate is unchanged;

after all the materials are added, the air is closed, the blanking machine is closed, and the materials are continuously mixed and stirred for 1 hour;

c: discharging, preparing to put a tray and a bag, and opening the starting discharging valve 3 to receive materials.

Compared with the prior art, the invention has the beneficial effects that:

according to the invention, when the device is used for processing the graphite coiled material, the graphite raw material for processing is added into the feeding bin, the corresponding mixture is quantitatively distributed at a fixed point through the batching component, and meanwhile, when the mixer is used for stirring, the graphite processing raw material falling from the feeding bin is scattered in advance from the top position through the arranged scattering component, so that the graphite raw material and the mixed material are mixed and contacted in advance at the top of the mixer, the mixing efficiency is improved, the graphite raw material is prevented from being excessively accumulated at the middle position in the mixer after falling from the feeding bin, and meanwhile, the mixed raw material is conveniently distributed and scattered from the bottom position through the arranged bottom distributing component at the bottom end position in the mixer, the accumulation of the mixed material is reduced, the mixing speed is improved, and the graphite raw material and the mixed material are conveniently and fully mixed.

Drawings

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

FIG. 2 is a schematic view of the present invention in partial cutaway configuration;

FIG. 3 is a schematic view of a longitudinal processing member;

FIG. 4 is a schematic view of the structure of the longitudinally movable assembly;

FIG. 5 is a schematic structural view of a bottom zone material distributing assembly;

FIG. 6 is an enlarged view of the area A in FIG. 3;

FIG. 7 is an enlarged view of the area B in FIG. 4;

fig. 8 is an enlarged structural view of the region C in fig. 5.

In the figure: 1-a mixer; 2-a feeding bin; 3-a blanking valve; 4-stirring the main shaft; 5-a dosing assembly; 6-breaking up the components; 7-a batching pipe; 8-a batching tank; 9-a transverse tube; 10-branch pipe; 11-a spray head; 12-star quantitative blanking machine; 13-a drive gear; 14-a transmission gear; 15-a rotating shaft; 16-a rotating plate; 17-longitudinal treatment members; 18-a limit sliding frame; 19-transverse breaker bar; 20-a pushing assembly; 21-a bottom distribution assembly; 22-an eccentric shaft; 23-a first crank arm; 24-a second crank arm; 25-crank arm rotating rod; 26-a hinged bracket; 27-a longitudinal moving member; 28-fixed beam; 29-a movable push plate; 30-a limit frame; 31-crushing the stems; 32-a first gear; 33-a second gear; 34-a steering gear; 35-rotating rods; 36-a material distribution table; 37-pushing the material; 38-a fluted plate; 39-a slide block; 40-a chute; 41-a material pushing rod; 42-a roller; 43-half gear; 44-a first bevel gear; 45-second bevel gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments 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.

Referring to fig. 1-8, the present invention provides a technical solution: the production process and equipment of graphite coil with very low burning loss solves the problems of high production efficiency, graphite is excessively accumulated at the middle position of a mixer 1 after falling down in a feeding bin 2, which is inconvenient for processing and mixing graphite raw materials, the design in the scheme comprises the mixer 1, the feeding bin 2 is connected with the top of the mixer 1, the bottom of the mixer 1 is connected with a blanking valve 3, the mixer 1 is internally connected with a stirring main shaft 4, a batching component 5 for quantitatively allocating corresponding mixed materials is connected between the mixer 1 and the feeding bin 2, the internal connection of blendor 1 has the graphite material of unloading in feeding storehouse 2 and the mixed material of unloading in batching subassembly 5 to scatter the subassembly 6 that breaks up of mixing in advance, and breaks up 6 one end of subassembly and is connected with the stirring main shaft 4 of blendor 1.

When the device carries out the compounding in this scheme of use and handles, add in feeding storehouse 2 through the graphite raw materials with graphite coiled material processing, simultaneously according to graphite coiled material processing batching, add corresponding antioxidant etc. to batching subassembly 5 department according to the ratio, when graphite raw materials fell down from feeding storehouse 2, the batching falls into the graphite raw materials of mixing feeding storehouse 2 department from batching subassembly 5 in step and carries out the hybrid processing, when batching and graphite raw materials fall into blendor 1 in step simultaneously, break up subassembly 6 through what the start was established and be convenient for break up graphite raw materials and the miscompound of whereabouts in step, be convenient for graphite raw materials and miscompound contact in advance, improve compounding speed.

The batching component 5 comprises a batching pipe 7 arranged at the top of the mixer 1, one end of the batching pipe 7 is communicated with a plurality of batching tanks 8, the other end of the batching pipe 7 is communicated with a transverse pipe 9, two ends of the transverse pipe 9 are respectively communicated with branch pipes 10, the bottoms of the branch pipes 10 are communicated with a plurality of spray heads 11, one ends of the spray heads 11 are arranged inside the mixer 1, the branch pipes 10 are distributed at two sides of the bottom of a feeding bin 2, a star-shaped quantitative blanking machine 12 is connected at the bottom of the feeding bin 2, the graphite raw materials are quantitatively blanked by the star-shaped quantitative blanking machine 12 by adding the graphite raw materials at the feeding bin 2, the antioxidant to be batched is added into one batching tank 8, compressed air is filled into the other batching tank 8, the antioxidant mixed graphite raw materials are firstly added into the mixer 1 together for mixing treatment, and the bottoms of the branch pipes 10 at the position pass through the plurality of spray heads 11, is convenient for multiple points and quantitatively adds into the mixer 1.

In this scheme break up subassembly 6 including connecting at 4 disconnected driving gears 13 of stirring main shaft, driving gear 13 top both sides are connected with two drive gear 14 respectively, are connected with pivot 15 on two drive gear 14, and pivot 15 is connected with 1 lateral wall of blendor, are connected with rotor plate 16 on one of them shown drive gear 14, and are connected with the vertical processing piece 17 of vertically breaking up the mixture of compounding on another drive gear 14, be connected with spacing sliding frame 18 on 1 inside both sides wall of blendor respectively, and sliding connection has horizontal pole 19 of breaing up between two spacing sliding frame 18, 19 one end of horizontal pole of breaing up is connected with and promotes subassembly 20, and promotes subassembly 20 and rotor plate 16 and be connected, the inside bottom of blendor 1 is connected with the bottom and divides material subassembly 21, and bottom divides material subassembly 21 and driving gear 13 to be connected. The pushing assembly 20 comprises an eccentric shaft 22 connected to the rotating plate 16, a first crank arm 23 is sleeved on the eccentric shaft 22, one end of the first crank arm 23 is connected with a second crank arm 24 in a cross mode, one end of the second crank arm 24 is movably connected to the inside of the limiting sliding frame 18, and one end, far away from the first crank arm 23, of the second crank arm 24 is connected with one end of the transverse scattering rod 19. The longitudinal processing piece 17 comprises a crank arm rotating rod 25 connected to the transmission gear 14, the other end of the crank arm rotating rod 25 is connected with the side wall of the mixer 1, a plurality of hinged supports 26 are connected to the crank arm rotating rod 25, one end of each hinged support 26 is hinged to a longitudinal moving piece 27 for longitudinally scattering mixtures, a fixed beam 28 is arranged at the top of each longitudinal moving piece 27, and two ends of each fixed beam 28 are connected to the side wall of the mixer 1 respectively. The longitudinal moving part 27 comprises a movable push plate 29 connected to the hinge support 26, the top of the movable push plate 29 is provided with a limiting frame 30, the top of the limiting frame 30 is connected with the fixed beam 28, one end of the movable push plate 29 is slidably connected to the inside of the limiting frame 30, and one side of the movable push plate 29 is connected with a crushing rod 31.

The specific operation process of the top scattering assembly 6 is as follows: under the stirring action of the stirring main shaft 4 of the mixer 1, the driving gear 13 connected to the stirring main shaft 4 starts to synchronously rotate, because two transmission gears 14 are meshed on two sides of the top of the driving gear 13 to move together, because the transmission gears 14 are connected with the rotating plate 16, under the power action of the transmission gears 14, the eccentric shaft 22 fixedly connected to the rotating plate 16 is convenient to eccentrically rotate, because the outer side of the eccentric shaft 22 is sleeved with the first crank arm 23, one end of the first crank arm 23 is crossed and connected with the second crank arm 24, and one end of the second crank arm 24 is movably connected inside the limit sliding frame 18, when the eccentric shaft 22 drives the first crank arm 23 to eccentrically rotate, the second crank arm 24 is convenient to be driven to slide along the limit sliding frame 18, and simultaneously, because the transverse scattering rod 19 is fixedly connected to the second crank arm 24, when the second crank arm 24 slides, the transverse scattering rod 19 is convenient to be driven to transversely reciprocate back and, because the two sides of the transverse scattering rod 19 are respectively connected with the transverse rods, the falling graphite raw material can be scattered transversely at the bottom of the feeding bin 2, the scattered graphite raw material can be contacted with the mixed material fully, meanwhile, because a crank rotating rod 25 is connected with one transmission gear 14, and a plurality of hinged brackets 26 are connected with the crank rotating rod 25, when the transmission gear 14 is driven by the driving gear 13 to rotate, the crank rotating rod 25 can be driven to rotate synchronously, because a plurality of hinged brackets 26 are connected with the crank rotating rod 25, and a movable push plate 29 is connected with the hinged brackets 26, when the hinged brackets 26 rotate, the movable push plate 29 slides upwards along the inside of the limit frame 30, similar to the movement of a piston, and a crushing rod 31 is connected with one side of the movable push plate 29, so that when the movable push plate 29 pushes upwards, one side of the hinged brackets 26 is connected with the transverse push rod in the scheme, make when vertically breaking up the raw materials, be convenient for the multiple spot carry out horizontal dispersion treatment, be convenient for drive crushing rod 31 upwards smash the graphite raw materials and the combined material of whereabouts, be convenient for mix in advance from vertical and horizontal graphite raw materials and the combined material to the unloading and break up the processing, just have combined material and graphite raw materials to carry out the intensive mixing, improve compounding efficiency.

The bottom material distribution assembly 21 comprises a first gear 32 connected to the outer side of the driving gear 13 in a meshing manner, a second gear 33 is meshed to the outer side of the driving gear 13, the second gear 33 is located on one side of the first gear 32, one side of the second gear 33 is connected with a steering gear 34, the steering gear 34 and the first gear 32 are both connected with a rotating rod 35, one end of the rotating rod 35 is connected with the inner wall of the mixer 1, a material distribution table 36 is arranged at the bottom end inside the mixer 1, the material distribution table 36 is located at the top of the discharging valve 3, two material pushing pieces 37 capable of pushing materials oppositely are arranged at the top of the material distribution table 36, one end of each material pushing piece 37 is connected with the rotating rod 35, the material pushing pieces 37 are arranged on tooth groove plates 38 at two sides of the material distribution table 36, two sliding blocks 39 are connected to the tooth groove plates 38, sliding grooves 40 are respectively arranged on two sides of the material distribution table, the utility model discloses a material distributing table, including four material distributing tables 36, four material distributing tables 35, four material distributing tables 36, four material distributing tables 35, four material.

The bottom distributing assembly 21 comprises the following specific operation steps: when the driving gear 13 drives the first gear 32 and the second gear 33, the rotation directions of the first gear 32 and the second gear 33 are the same, at this time, under the action of the steering gear 34, the rotation direction of the second gear 33 is conveniently adjusted to the position where the first gear 32 is opposite, at this time, the rotating rod 35 fixed on the first gear 32 and the steering gear 34 rotates in opposite directions, at the same time, because the second bevel gear 45 is sleeved outside the rotating rod 35, at this time, the two second bevel gears 45 start to rotate in opposite directions, because one end of the roller 42 is connected with the half gear 43, one end of the roller 42 far away from the half gear 43 is connected with the first bevel gear 44, when the two second bevel gears 45 with opposite rotation directions and the first bevel gear 44 are meshed with each other, the two rollers 42 are conveniently driven to rotate in opposite directions, at this time, the half gear 43 fixed outside the roller 42 is convenient to drive the toothed groove plate 38 meshed therewith to move in opposite, because the chute plate 38 is fixedly connected with the pushing rod 41, the pushing rod 41 disperses the fallen mixed raw materials and the mixture from the material distributing table 36.

The production process of the graphite coiled material with ultra-low ignition loss comprises the following steps of using the manufacturing equipment to perform processing treatment:

a: physical preparation and material ratio, wherein EG: phosphoric acid: phosphate =: 100: 0.5-1.5: 1-2,

the EG preparation range is less than or equal to 800kg, the capacity of the mixing machine is less than or equal to 1000kg,

preparing an antioxidant, and calculating according to the EG amount ratio;

b: feeding, mixing and stirring, starting a star-shaped quantitative blanking machine 12 at 50-75 kg/min, and starting a mixer 1 at a stirring speed of 80-100 revolutions/min;

opening compressed air, starting a pipeline valve of the dosing tank 8, and checking whether the spraying is normal or not at the flow rate of 10 kg/min;

after the antioxidant is added, a valve is switched to open the proportioning tank 8, and the flow rate is unchanged;

after all the materials are added, the air is closed, the blanking machine is closed, and the materials are continuously mixed and stirred for 1 hour;

c: discharging, preparing to put a tray and a bag, and opening the starting discharging valve 3 to receive materials.

The power of the stirring main shaft 4 that utilizes in this scheme drives driving gear 13 and drive gear 14 in step and rotates for transversely break up pole 19 and transversely break up the processing with the mixture, be convenient for simultaneously transversely break up the processing and vertically ejecting the mixture of breaking up, utilize first gear 32, second gear 33 and steering gear 34 combined action under driving gear 13 bottom, realized two dwang 35 antiport, thereby realized dividing the material of whereabouts raw materials and handled.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides an ultralow loss of ignition graphite coiled material production manufacture equipment, includes blendor (1), blendor (1) top is connected with feeding storehouse (2), and blendor (1) bottom is connected with baiting valve (3), blendor (1) internal connection has stirring main shaft (4), its characterized in that: be connected with batching subassembly (5) that the corresponding mixed material of ration configuration between blendor (1) and feeding storehouse (2), blender (1) internal connection has the graphite material of unloading in feeding storehouse (2) and the mixed material of unloading in batching subassembly (5) to scatter in advance and mix scattering subassembly (6), and scatters subassembly (6) one end and is connected with stirring main shaft (4) of blender (1).

2. The production and manufacturing equipment of the graphite coiled material with ultra-low ignition loss as claimed in claim 1, wherein: batching subassembly (5) is including setting up batching pipe (7) at blendor (1) top, batching pipe (7) one end UNICOM has a plurality of batching jars (8), and batching pipe (7) other end UNICOM has horizontal pipe (9), horizontal pipe (9) both ends UNICOM respectively has branch pipe (10), branch pipe (10) bottom UNICOM has a plurality of shower nozzles (11), and shower nozzle (11) one end is installed inside blendor (1), branch pipe (10) distribute in feeding storehouse (2) bottom both sides, and feeding storehouse (2) bottom is connected with star type ration blanking machine (12).

3. The production and manufacturing equipment of the graphite coiled material with ultra-low ignition loss as claimed in claim 1, wherein: the scattering assembly (6) comprises a driving gear (13) connected to one end of a stirring main shaft (4), two transmission gears (14) are connected to two sides of the top of the driving gear (13) respectively, a rotating shaft (15) is connected to the two transmission gears (14), the rotating shaft (15) is connected to the side wall of the mixer (1), one of the transmission gears (14) is connected with a rotating plate (16), the other transmission gear (14) is connected with a longitudinal processing piece (17) for longitudinally scattering a mixed mixture, two side walls inside the mixer (1) are connected with limiting sliding frames (18) respectively, a transverse scattering rod (19) is connected between the two limiting sliding frames (18) in a sliding mode, one end of the transverse scattering rod (19) is connected with a pushing assembly (20), the pushing assembly (20) is connected with the rotating plate (16), and a bottom distributing assembly (21) is connected to the bottom end inside the mixer (1), and the bottom material distributing component (21) is connected with the driving gear (13).

4. The production and manufacturing equipment of the graphite coiled material with the ultra-low ignition loss as claimed in claim 3, wherein: the pushing assembly (20) comprises an eccentric shaft (22) connected to the rotating plate (16), a first crank arm (23) is sleeved on the eccentric shaft (22), one end of the first crank arm (23) is connected with a second crank arm (24) in an intersecting mode, one end of the second crank arm (24) is movably connected to the inside of the limiting sliding frame (18), and one end, far away from the first crank arm (23), of the second crank arm (24) is connected with one end of the transverse scattering rod (19).

5. The production and manufacturing equipment of the graphite coiled material with the ultra-low ignition loss as claimed in claim 3, wherein: vertical processing member (17) are including connecting crank arm bull stick (25) on drive gear (14), and the other end and blendor (1) lateral wall of crank arm bull stick (25) are connected, be connected with a plurality of articulated supports (26) on crank arm bull stick (25), and articulated support (26) one end articulates has vertical moving part (27) of vertically breaking up the mixture, and vertical moving part (27) top is equipped with fixed beam (28), fixed beam (28) both ends are connected in blendor (1) lateral wall respectively.

6. The production and manufacturing equipment of the graphite coiled material with the ultra-low ignition loss as claimed in claim 5, wherein: vertical moving part (27) is including connecting activity push pedal (29) on articulated bracket (26), activity push pedal (29) top is equipped with spacing frame (30), and spacing frame (30) top is connected with fixed beam (28), activity push pedal (29) one end sliding connection is inside spacing frame (30), and activity push pedal (29) one side is connected with crushing pole (31).

7. The production and manufacturing equipment of the graphite coiled material with the ultra-low ignition loss as claimed in claim 3, wherein: divide material subassembly (21) in bottom to connect first gear (32) in driving gear (13) outside including the meshing, the meshing has second gear (33) in driving gear (13) outside, and second gear (33) are located first gear (32) one side, second gear (33) one side is connected with steering gear (34), and all is connected with dwang (35) on steering gear (34) and first gear (32), dwang (35) one end and blendor (1) inner wall connection, the inside bottom of blendor (1) is equipped with branch material platform (36), divide material platform (36) to be located unloading valve (3) top, divide material platform (36) top to be equipped with material pushing part (37) that two relative materials pushed, and material pushing part (37) one end is connected with dwang (35).

8. The production and manufacturing equipment of the graphite coiled material with ultra-low ignition loss as claimed in claim 7, wherein: the material pushing part (37) is arranged on the toothed groove plates (38) at two sides of the material distributing platform (36), two sliding blocks (39) are connected on the tooth groove plate (38), sliding grooves (40) are respectively arranged on two sides of the material distribution platform (36), the sliding block (39) is connected with the sliding chute (40) in a sliding way, one side of the tooth groove plate (38) is connected with a material pushing rod (41), the material pushing rod (41) is positioned at the top of the material distributing platform (36), two sides of the material distributing platform (36) are respectively connected with a rolling shaft (42), one end of the rolling shaft (42) is connected with a half gear (43), the half gear (43) is meshed with the toothed groove plate (38), one end of the rolling shaft (42) far away from the half gear (43) is connected with a first helical gear (44), the outer side of the rotating rod (35) is connected with a second bevel gear (45), and the first bevel gear (44) is meshed with the second bevel gear (45).

9. A production process of an ultra-low ignition loss graphite coil comprises the steps of processing by using the manufacturing equipment in claim 1, and is characterized in that:

a: physical preparation and material ratio, wherein EG: phosphoric acid: phosphate =: 100: 0.5-1.5: 1-2,

the preparation range of EG is less than or equal to 800kg (the capacity of a mixer is less than or equal to 1000 kg),

preparing an antioxidant, and calculating according to the EG amount ratio;

b: feeding, mixing and stirring, starting a star-shaped quantitative blanking machine (12) at 50-75 kg/min, and starting a mixer (1) at a stirring speed of 80-100 revolutions/min;

opening compressed air, starting a pipeline valve of the dosing tank (8), and enabling the flow rate to be 10kg/min (checking whether the spraying is normal or not);

after the antioxidant is added, a valve is switched to open a dosing tank (8), and the flow rate is unchanged;

after all the materials are added, the air is closed, the blanking machine is closed, and the materials are continuously mixed and stirred for 1 hour;

c: discharging, preparing to put a tray and a bag, and opening a starting discharging valve (3) to receive materials.

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