CN106903140B - A extrude material machine of receiving for lithium electricity new forms of energy - Google Patents

Abstract

The invention discloses an extrusion material receiving machine for lithium battery new energy, which is mainly used for collecting corner waste materials generated in die cutting of an electrode plate laser forming machine and compressing the volume of the corner waste materials; utilize mobile air, for the leftover bits provide directive property's power, through continuous extrusion with decide into the graininess, the graininess leftover bits are transported to the department of filtering through the negative pressure, dust and the graininess leftover bits and air separation that the filter core produced when will deciding, dust and graininess leftover bits get into appointed holding bag through continuous unloader.

Description

A extrude material machine of receiving for lithium electricity new forms of energy

Technical Field

The invention relates to the technical field of industrial dust removal, in particular to an extrusion material receiving machine for new energy of lithium batteries.

Background

In the production process of new forms of energy lithium electricity, when adopting laser forming machine to carry out the cross cutting, produce the waste material and the dust of pole piece leftover bits, to the processing of these waste materials, the general processing mode of enterprise all directly carries out artifical compaction bagging-off processing, also or utilizes the compaction device of cross cutting machine area to carry out the compaction of crude effect, carries out artifical secondary compaction and bagging-off again. The compression effect of the treatment method is not obvious, and the very frequent material receiving work can be caused, so that the production efficiency is reduced. In addition, the frequent bagging operation in the workshop can shake off the dust on the leftover materials, and pollute the clean environment of the dust-free workshop.

Therefore, in enterprises of new energy lithium batteries, equipment technologies capable of effectively solving the problems of pole piece treatment and related environmental protection are urgently needed.

Disclosure of Invention

The technical problem to be solved by the invention is to provide an extrusion material collecting machine for lithium battery new energy aiming at the defects of the prior art, which is used for collecting and crushing leftover materials and dust generated in pole piece cutting, providing directional power for the leftover materials and the dust by utilizing flowing air, and collecting the crushed material dust after gas-solid filtering and separation.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows: the utility model provides a material machine is received in extrusion for lithium electricity new forms of energy which characterized in that: the device comprises a fan unit, a filtering unit, a crushed aggregate extruding unit and a crushed aggregate collecting unit; the fan unit comprises a fan, an air inlet of the fan is communicated with an air outlet of the filtering unit, and an air outlet of the fan is communicated with outside air; the filtering unit comprises a filtering bin and a filtering assembly arranged in the filtering bin, the filtering bin is provided with a main air inlet, a discharge outlet and an exhaust port, the discharge outlet is communicated with the crushed aggregate collecting unit, and the main air inlet is communicated with a discharge outlet of the crushed aggregate extruding unit to form a main air channel; the extrusion crushed aggregates unit comprises an extrusion cutter, a feed inlet and a discharge outlet, wherein the feed inlet is communicated with an external material source.

In the technical scheme, a pressurizing box is arranged between the feeding hole and the extrusion cutting machine, a narrow opening at the bottom of the pressurizing box is communicated with the extrusion cutting machine, and a wide opening at the top of the pressurizing box is communicated with the feeding hole.

In the technical scheme, a ventilation separation net is arranged in the pressurization box to divide the pressurization box into two regions, namely a region I and a region II; meanwhile, the wide port is divided into two openings, namely a wide port I and a wide port II; the first area is communicated with the feeding hole through a first wide opening and is communicated with the extrusion cutter through a narrow opening; and the second region is communicated with a first auxiliary air inlet of the filtering unit through a second wide opening to form an auxiliary air passage, or the second region is communicated with a second auxiliary air inlet on the main air passage through a second wide opening to form an auxiliary air passage.

In the above technical scheme, the separation net comprises an upper plate and a lower net from top to bottom, and air in the first area enters the second area from the lower net.

In the technical scheme, the wide port two is provided with a wind adjusting and absorbing cover, the wind adjusting and absorbing cover is provided with an upper opening communicated with the first auxiliary air inlet or the second auxiliary air inlet, and a lower opening communicated with the wide port two; the air adjusting suction hood is internally provided with an air adjusting device, and the air adjusting device comprises a rotating shaft and a wind shield arranged on the rotating shaft; the rotating shaft is driven to drive the wind shield to adjust the flow of the wind adjusting and absorbing cover by controlling the handle outside the wind adjusting and absorbing cover.

In the technical scheme, the filtering component comprises a conical anti-static filter cylinder, a pulse valve, an air storage tank and a discharge valve.

In the above technical scheme, crushed aggregates collection unit is including collecting bag mount pad and collecting bag, should collect the bag mount pad install in filter unit's bin outlet, it installs on collecting the bag mount pad to collect the bag.

In the technical scheme, the collecting bag mounting seat comprises a cylindrical main body, the upper opening of the cylindrical main body is communicated with the discharge port, the lower opening is flanged outwards to form an annular groove with an upward opening, and the collecting bag is arranged in the annular groove.

In the technical scheme, the collecting bag is a cylindrical plastic bag with openings at two ends, the opening at the top of the collecting bag is fixedly sleeved on the cylindrical main body through a fastener, and the part below the opening at the top of the collecting bag is folded and arranged in the annular groove along the axial direction; when the collecting bag is used, the opening at the bottom of the collecting bag is pulled down to form a cover body which surrounds the periphery of the lower opening of the cylindrical main body, and the opening of the cover body is sealed by a fastening piece to be used as the bag bottom of the collecting bag.

The invention has the beneficial effects that:

a. the filtering unit adopts a conical anti-static filter cylinder, so that the dust attachment and the discharge risk are effectively reduced due to high back-flushing area and conductive treatment; the machine frame is made of 304 stainless steel or SPCC metal plates, protective paint is sprayed on the surface of the SPCC metal plates, conductive paint is additionally sprayed in the filter silo, and static electricity which is possibly generated is dredged and decompressed.

b. The discharge valve runs at regular time to avoid overhigh load caused by long-time work, the bearing position is provided with a temperature control probe, and the machine is stopped by overtemperature alarm;

c. automatic pulse back flushing deashing, differential pressure induction, and alarming when the differential pressure of the equipment is abnormal;

d. the continuous bagging is free from stopping and material receiving operation, and the seamless sleeving greatly reduces the dust overflow.

e. The motor is cooled by flowing air flow

f. The air quantity of the pressurizing box is adjusted through an air adjusting device on the air adjusting suction cover. Because the airflow bypasses the crushed aggregates with larger wind resistance, the wind speed from the leftover materials to the machine road section can be effectively improved. The upper auxiliary air passage of the air adjusting suction hood is merged into the main air passage at the discharge port of the pulverizer, so that the air speed in the main air passage is effectively increased, and the condition of crushed aggregates accumulation is avoided.

g. The leftover material to be processed vertically enters the pressurizing box from the feeding hole, directly collides to the crushing structure due to inertia, is transferred to the lower part under the driving of the cutter, and is extruded and cut into granular materials by the extrusion between the cutter and the cavity of the extrusion cutter. Most of the processed scraps are conveyed into a filter bin from a dust absorption pipeline below the crusher for gas-solid separation. A small part of the particles are pumped away from the secondary air passage through the separation net of the pressurizing box.

h. The machine has a pulse back-flushing self-cleaning function, dust attached to the filter element is shaken off at regular time, and then slides into the continuous discharge valve through the funnel, and then enters the continuous collection bag through the discharge valve. The discharge valve has certain sealing function.

i. During blowback air current can conduct to the pressure boost case through the pressure boost pipeline, and the air hammer can shake the convulsions one side partition adsorbed particulate matter on the net and fall.

Drawings

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

FIG. 2 is a schematic diagram of the internal structure of the first embodiment of the present invention;

FIG. 3 is a schematic diagram of the internal structure of the first embodiment of the present invention;

FIG. 4 is a schematic diagram of the internal structure of a second embodiment of the present invention;

FIG. 5 is a schematic view of the internal structure of a second embodiment of the present invention;

FIG. 6 is a schematic view of the construction of the plenum box of the present invention;

FIG. 7 is a schematic view of the construction of the collection bag mount of the present invention;

FIG. 8 is a schematic view of the operation of the collection bag of the present invention;

fig. 9 is a schematic flow chart of the operation of the continuous bagging of the present invention.

In the figure, 1, a fan unit; 2. a filtration unit; 3. extruding the crushed material unit; 4. a crushed material collecting unit; 5. an electric cabinet; 7. a differential pressure switch; 8. dust

101. A fan; 102. an air inlet; 103. an air outlet; 104. a filter;

201. a filtering bin; 202. a primary air inlet; 203. a discharge outlet; 204. an exhaust port; 205. a wind-shielding spoiler; 206. a tapered anti-static filter cartridge; 207. a pulse valve; 208. a gas storage tank; 209. a discharge valve; 210. a funnel; 211. a first secondary air inlet; 212. a main air passage; 213. a secondary airway; 214. a second secondary inlet;

301. an extrusion clipper; 302. a feed inlet; 303. a discharge port; 304. a pressurizing box; 305. wide opening; 306. a narrow opening; 307. separating the net; 308. a first area; 309. a second area; 3051. A first wide opening; 3052. a second wide opening; 3071. an upper plate; 3072. off-line; 310. a partition plate; 311. a wind adjusting suction hood; 312. a wind adjusting device; 3121. a rotating shaft; 3122. a wind deflector; 3123. a handle; 313. a transparent steel wire tube;

401. a collection bag mounting seat; 402. a collection bag; 403. binding a belt; 4011. a cylindrical main body; 4012. an annular groove; 402a, showing the folded collection bag; 402b, showing the collection bag when forming the enclosure; 402c, showing the collection bag after the cover's lower opening has been tied; 402d, showing the collection bag above divided by two ties; 402e, showing the collection bag below divided by two ties; 404. indicating a trim line.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 9, an extrusion material collecting machine for new energy of lithium batteries comprises a fan unit 1, a filtering unit 2, an extrusion crushed material unit 3 and a crushed material collecting unit 4; fan unit 1 sets up in the top of extrusion crushed aggregates unit 3, filter unit 2 sets up on one side of fan unit 1, crushed aggregates collection unit 4 sets up in filter unit 2's below. The positions of all the units are reasonably designed, so that the whole structure is compact and does not occupy space.

Specifically, the fan unit 1 includes a fan 101, in this embodiment, a medium pressure fan is adopted, an air inlet 102 of the fan 101 is communicated with an air outlet 204 of the filter unit 2, and an air outlet 103 is communicated with outside air; the air outlet 103 is provided with a filter 104, so that the air which enters the fan 101 through the filter unit 2 and is discharged from the air outlet 103 is filtered by the filter 104 again, and the air discharged to the outside is ensured to reach the discharge standard. The filter 104 in this embodiment adopts a glass fiber filter layer, and sealing cotton is adhered to the air inlet side of the filter 104.

Specifically, the filter unit 2 includes a filter bin 201 and a filter assembly arranged in the filter bin 201, the filter bin 201 is provided with a main air inlet 202, a discharge port 203 and an exhaust port 204, the discharge port 203 is communicated with a crushed material collecting unit 4, and the main air inlet 202 is communicated with a discharge port 303 of an extrusion crushed material unit 3. A wind-shielding spoiler 205 is disposed at the main air inlet 202, the wind-shielding spoiler 205 is spaced from the main air inlet 202, and four corners of the wind-shielding spoiler 205 are fixed to the filtering bin 201 by fixing members.

Wherein the filter assembly comprises a tapered anti-static filter cartridge 206, a pulse valve 207, an air reservoir 208 and a discharge valve 209. And simultaneously comprises an electric cabinet 5, an oil-water separator and a differential pressure switch 7. The high back-flushing area and the conductive treatment of the tapered anti-static filter cylinder 206 effectively reduce dust accretion and discharge risks. The gas storage tank 208 carries out blowback deashing through the pulse valve 207, regularly shakes the adnexed dust on the filter core and falls, and the hopper 210 landing is to discharge valve 209 in, and discharge valve 209 has certain sealed effect. During back blowing, the airflow is conducted into the pressurizing box 304 through the secondary air passage 213, and the air hammer shakes off the particles adsorbed on the partition net 307 on the air draft side. Whether the equipment differential pressure is abnormal or not should be monitored using the differential pressure sensing of the differential pressure switch 7. The discharge valve 209 is star type discharge valve 209, and the ration is arranged the dust to crushed aggregates collection unit 4 in, and the timing operation avoids the high load that long-time work brought effectively to set up the temperature control probe in discharge valve 209's bearing position, report to the police and shut down when the bearing temperature is too high, avoid the damage of machine. The oil-water separator collects and separates oil and moisture of the air in the filtering unit 2. The electric cabinet 5 controls various electronic devices such as the differential pressure switch 7.

Specifically, the crushing unit 3 comprises an extruding and cutting machine 301, a feeding hole 302 and a discharging hole 303, wherein the feeding hole 302 is communicated with an external material source.

According to the Bernoulli principle of fluid, the flow velocity of the fluid is larger when the fluid passes through a pipe with a small section from a pipe with a large section; therefore, in order to enhance the aerodynamic force for driving the waste material to move, a pressurizing box 304 is arranged between the feed port 302 and the extrusion cutter 301, a narrow port 306 at the bottom of the pressurizing box 304 is communicated with the extrusion cutter 301, and a wide port 305 at the top of the pressurizing box 304 is communicated with the feed port 302, namely, the pressurizing box 304 has a shape with a gradually-reduced cross section from top to bottom.

The main air passage 212 communicated between the filter unit 2 and the discharge hole 303 in the extrusion cutter 301 is the only driving force, and in the process of crushing, dust can be gathered in the cavity of the extrusion cutter 301, so that the main air passage 212 can be blocked to a certain extent, and the main air passage is mainly blocked between waste materials and the extrusion cutter 301. Therefore, in this embodiment, a ventilation screen 307 is disposed in the pressure increasing tank 304 to divide the pressure increasing tank 304 into two regions, namely, a region one 308 and a region two 309; meanwhile, the wide port 305 is also divided into two openings, namely a wide port I3051 and a wide port II 3052; the first area 308 is communicated with the feed inlet 302 through a first wide opening 3051 and is communicated with the extrusion cutter 301 through a narrow opening 306; the second area 309 is communicated with the first secondary air inlet 211 of the filter unit 2 through the second wide opening 309 to form a secondary air passage 213, as shown in the first embodiment of fig. 3 and 4; or the second area 309 is communicated with the second secondary air inlet 214 on the primary air passage 212 through the second wide opening 3052 to form a secondary air passage 213, as in the second embodiment of fig. 5 and 6; the formation of the secondary air channel 213 in both of these solutions can accelerate the wind speed of the primary air channel 212, thereby reducing the possibility of accumulation of particles due to insufficient wind speed and improving the stability of the waste material feeding.

The screen 307 includes an upper plate 3071 and a lower screen 3072 from top to bottom, and the air in the first area 308 enters the second area 309 from the lower screen 3072. When the scraps enter the wide opening 305 of the pressurizing box 304, in order to ensure that the scraps do not block the wide opening 305, the upper plate 3071 of the partition net 307 is not provided with holes, so that the scraps can smoothly pass through the wide opening one 3051 to reach the inside of the pressurizing box 304.

The second wide port 3052 is provided with an air adjusting and sucking cover 311, the air adjusting and sucking cover 311 is provided with an upper opening communicated with the first auxiliary air inlet 211 or the second auxiliary air inlet 214, in this embodiment, the air adjusting and sucking cover is communicated with the second auxiliary air inlet 214, the first auxiliary air inlet 211 is blocked by a sealing cover, and the air adjusting and sucking cover 311 is provided with a lower opening communicated with the second wide port 3052; the air adjusting suction hood 311 is internally provided with an air adjusting device 312, and the air adjusting device 312 comprises a rotating shaft 3121 and a wind shield 3122 arranged on the rotating shaft 3121; the handle 3123 outside the wind adjustment suction hood 311 is controlled to drive the rotating shaft 3121 to drive the wind blocking plate 3122 to adjust the flow rate of the wind adjustment suction hood 311. The upper opening of the wind adjusting suction cover 311 is connected with a transparent steel wire pipe 313, and the wind adjusting device 312 is arranged in the transparent steel wire pipe 313, so that the worker can clearly observe the wind adjusting state in the wind adjusting suction cover from the outside; of course, a mark may be provided on the handle 3123, and the wind adjustment state may be known by observing the direction of the mark.

Specifically, the trash collecting unit 4 includes a collecting bag mounting seat 401 and a collecting bag 402, the collecting bag mounting seat 401 is mounted on the discharge port 203 of the filter unit 2, and the collecting bag 402 is mounted on the collecting bag mounting seat 401.

Wherein, the collection bag mount pad 401 includes a tube-shape main part 4011, the upper shed of tube-shape main part 4011 with bin outlet 203 intercommunication, the downward opening turn-ups forms an annular groove 4012 that the opening faces up, collection bag 402 is arranged in this annular groove 4012.

Wherein, the collecting bag 402 is a cylindrical plastic bag with openings at two ends, the top opening of the collecting bag 402 is fixedly sleeved on the cylindrical main body 4011 by a fastener (a first binding tape), and the lower part of the top opening of the collecting bag 402 is folded and placed in the annular groove 4012 along the axial direction, as shown in A in FIG. 7; in use, the bottom opening of the collecting bag 402 is pulled down to form a cover body surrounding the lower opening of the cylindrical main body 4011, as shown in fig. 7B; the opening of the enclosure is sealed with fasteners (secondary ties) as the bag bottom of the collection bag 402, as shown at C in fig. 7. In this embodiment, the fastener is a tie 403. After the collection bag 402 is loaded with a sufficient amount of dust, the bag body of the collection bag 402 below the lower opening of the cylindrical main body 4011 is bound once (third binding tape 403 and fourth binding tape 403) at a distance from each other, and cut (along a cutting line) between the two bound places, as shown in fig. 7D; while a sufficient number of collection bags 402 are being separated from the body, the next collection bag 402 is formed to seal the bottom of the bag, as shown at E in fig. 7. In addition, the overflow of dust can be greatly reduced in the process.

The above examples are intended to illustrate rather than to limit the invention, and all equivalent changes and modifications made by the methods described in the claims of the present invention are intended to be included within the scope of the present invention.

Claims (5)

1. The utility model provides a material machine is received in extrusion for lithium electricity new forms of energy which characterized in that: the device comprises a fan unit, a filtering unit, a crushed aggregate extruding unit and a crushed aggregate collecting unit; the fan unit comprises a fan, an air inlet of the fan is communicated with an air outlet of the filtering unit, and an air outlet of the fan is communicated with outside air; the filtering unit comprises a filtering bin and a filtering assembly arranged in the filtering bin, the filtering bin is provided with a main air inlet, a discharge outlet and an exhaust port, the discharge outlet is communicated with the crushed material collecting unit, and the main air inlet is communicated with a discharge outlet of the crushed material extruding unit to form a main air channel; the extrusion crushing unit comprises an extrusion cutting machine, a feeding port and a discharging port, the feeding port is communicated with an external material source, a pressurizing box is arranged between the feeding port and the extrusion cutting machine, a narrow opening at the bottom of the pressurizing box is communicated with the extrusion cutting machine, a wide opening at the top of the pressurizing box is communicated with the feeding port, and a ventilation separation net is arranged in the pressurizing box to divide the pressurizing box into two regions, namely a region I and a region II; meanwhile, the wide port is divided into two openings, namely a wide port I and a wide port II; the first area is communicated with the feeding hole through a first wide opening and is communicated with the extrusion cutter through a narrow opening; the second area is communicated with a first auxiliary air inlet of the filtering unit through a second wide opening to form an auxiliary air passage, or the second area is communicated with a second auxiliary air inlet on the main air passage through a second wide opening to form an auxiliary air passage, the separation net comprises an upper plate and a lower net from top to bottom, air in the first area enters the second area from the lower net, the second wide opening is provided with a wind adjusting suction cover, the wind adjusting suction cover is provided with an upper opening communicated with the first auxiliary air inlet or the second auxiliary air inlet, and a lower opening communicated with the second wide opening; the air adjusting suction hood is internally provided with an air adjusting device, and the air adjusting device comprises a rotating shaft and a wind shield arranged on the rotating shaft; the rotating shaft is driven to drive the wind shield to adjust the flow of the wind adjusting and absorbing cover by controlling the handle outside the wind adjusting and absorbing cover.

2. The extrusion material receiving machine for the lithium battery new energy source is characterized in that: the filter assembly comprises a conical anti-static filter cylinder, a pulse valve, an air storage tank and a discharge valve.

3. The extrusion material collecting machine for the lithium battery new energy according to claim 1, characterized in that: the crushed aggregates collection unit is including collecting the bag mount pad and collecting the bag, should collect the bag mount pad install in filter unit's bin outlet, it installs on collecting the bag mount pad to collect the bag.

4. The extrusion material receiving machine for the lithium battery new energy source is characterized in that: the collecting bag mounting seat comprises a cylindrical main body, an upper opening of the cylindrical main body is communicated with the discharge port, an annular groove with an upward opening is formed by flanging an outer lower opening, and the collecting bag is arranged in the annular groove.

5. The extrusion material receiving machine for the lithium battery new energy source is characterized in that: the collecting bag is a cylindrical plastic bag with openings at two ends, the opening at the top of the collecting bag is fixedly sleeved on the cylindrical main body through a fastener, and the part below the opening at the top of the collecting bag is folded and arranged in the annular groove along the axial direction; when the collecting bag is used, the opening at the bottom of the collecting bag is pulled down to form a cover body which surrounds the periphery of the lower opening of the cylindrical main body, and the opening of the cover body is sealed by a fastening piece to be used as the bag bottom of the collecting bag.

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