CN223188194U - An inverted vacuum belt line - Google Patents

Abstract

The utility model discloses an inverted-hanging vacuum belt line which comprises a belt conveying mechanism, a fixed lifting mechanism and a vacuum cavity assembly, wherein the belt conveying mechanism comprises a power seat, a conveying driving assembly, guide rollers and a vacuum belt, the conveying driving assembly, the guide rollers and the vacuum belt are arranged on the power seat, the guide rollers are arranged on a vacuum belt conveying path, the vacuum belt is wound on the guide rollers, the conveying driving assembly is used for driving the vacuum belt to rotate, the vacuum cavity assembly comprises a vacuum plate and a plurality of vacuum pipelines, the vacuum plate is arranged below the power seat in a hanging mode, the vacuum pipelines are arranged on two opposite sides of the vacuum plate, the fixed lifting mechanism is used for supporting the lifting belt conveying mechanism, the fixed lifting mechanism comprises a lifting installation seat and a lifting driving assembly, the power seat is connected with the lifting installation seat in a sliding mode along the vertical direction, and the lifting driving assembly is used for driving the power seat to lift. The utility model has the advantages of large lifting height and rapid and convenient structure maintenance and replacement.

Description

Inverted-hanging vacuum belt line

Technical Field

The utility model relates to the technical field of lithium battery production, in particular to a reverse-hanging vacuum belt line.

Background

At present, the vacuum conveying on the cutting and stacking integrated machine is to convey the qualified pole pieces after cutting to each lamination station, so that the automatic circulation of the pole pieces is realized, wherein the reverse hanging vacuum belt line is reverse adsorption conveying, and the reverse visual detection and bad rejection in the continuous high-speed conveying process of the pole pieces are realized. The traditional hanging structure that is applied to length extremely short pole piece and hangs belt line in falling adopts the frame base plate, and to the conveying mechanism cavity of longer pole piece, its cantilever is longer and whole heavier, if adopt traditional structure can appear leaning on inboard part maintenance difficulty, and cause inboard takeover to adsorb negative pressure not enough, outside bearing structure unstable scheduling circumstances.

In view of the above, the present utility model aims to provide a new technical solution to solve the existing technical problems.

Disclosure of utility model

In order to overcome the defects of the prior art, the utility model provides the inverted-hanging vacuum belt line, which solves the problem of high maintenance difficulty of the existing structure.

The technical scheme adopted for solving the technical problems is as follows:

The utility model provides a hang vacuum belt line upside down, includes belt conveying mechanism, fixed elevating system, vacuum cavity subassembly, belt conveying mechanism includes the power seat and set up in conveying drive assembly, guide roll and the vacuum belt on the power seat, a plurality of the guide roll set up in on the vacuum belt conveying route, the vacuum belt winds and establishes on the guide roll, conveying drive assembly is used for driving the vacuum belt rotates;

The vacuum cavity assembly comprises a vacuum plate and a plurality of vacuum pipelines, the vacuum plate is mounted below the power seat in a hanging manner, and the vacuum pipelines are arranged on two opposite sides of the vacuum plate;

The fixed lifting mechanism is used for supporting and lifting the belt conveying mechanism, the fixed lifting mechanism comprises a lifting installation seat and a lifting driving assembly, the power seat is slidably connected with the lifting installation seat along the vertical direction, and the lifting driving assembly is used for driving the power seat to lift.

In the above structure, the lifting driving assembly comprises a lifting cylinder I, a connecting plate I is slidingly connected to the lifting mounting seat, the power seat is fixedly connected to the connecting plate I, a piston rod of the lifting cylinder I is fixedly connected to the connecting plate I and used for driving the connecting plate I to slide in the lifting mounting seat along the vertical direction, an oil pressure buffer is fixedly connected to the lifting mounting seat, and a buffer mounting block is fixedly connected to the connecting plate I and connected with the oil pressure buffer.

In the above structure, the vacuum belt tensioning device further comprises an automatic tensioning mechanism, the automatic tensioning mechanism comprises a tensioning installation seat, a tensioning roller and a tensioning cylinder, the tensioning installation seat is slidably connected with the lifting installation seat along the vertical direction, a tensioning fixing seat is fixedly connected with the tensioning installation seat, the tensioning cylinder is fixedly connected with the tensioning fixing seat, the tensioning roller is arranged on the tensioning fixing seat in a lifting manner along the vertical direction, the tensioning cylinder is used for driving the tensioning roller to lift, and the vacuum belt is wound on the tensioning roller.

In the above structure, the lifting driving assembly further comprises a lifting air cylinder II, a connecting plate II is connected to the lifting installation seat in a sliding manner, the tensioning installation seat is fixedly connected to the connecting plate II, and a piston rod of the lifting air cylinder II is fixedly connected to the connecting plate II and used for driving the connecting plate II to slide in the lifting installation seat along the vertical direction.

In the above structure, the automatic tensioning mechanism further comprises a guide idler and a tensioning support plate, the guide idler is fixedly connected to the tensioning installation seat, the two groups of guide idlers are symmetrically arranged on two sides of the tensioning roller, the guide idler is used for supporting the vacuum belt, and the tensioning support plate is fixedly arranged on the vacuum plate and fixedly connected with the tensioning fixing seat.

In the above structure, the fixed lifting mechanism further comprises a plurality of groups of support adjusting components arranged below the vacuum cavity component, the support adjusting components are arranged on one side of the belt conveying mechanism opposite to the lifting driving component, each support adjusting component comprises a support adjusting rod and a support fixing rod, the support adjusting rods are in threaded connection with the support fixing rods, and one ends, far away from the support fixing rods, of the support adjusting rods are abutted to the vacuum plate.

In the structure, four vacuum belts are arranged side by side, guide plates are arranged between adjacent vacuum belts, and the tops of the guide plates are flush with the surfaces of the vacuum belts;

The vacuum plate end part is fixedly connected with a correction mounting plate, correction rollers which are in one-to-one correspondence with the four vacuum belts are arranged on the correction mounting plate, two ends of each correction roller are connected with adjusting blocks, and the adjusting blocks are fixedly connected with the correction mounting plate.

In the structure, the conveying driving assembly comprises a servo motor and a driving roller, the servo motor is fixedly arranged on the power seat, the vacuum belt is wound on the driving roller, the output end of the servo motor is connected with a speed reducer, and the speed reducer is connected with the driving roller and is used for driving the driving roller to rotate so as to drive the vacuum belt to rotate.

In the above structure, the automatic material beating mechanism is further comprised, the automatic material beating mechanism comprises a material beating support frame, a material beating driving assembly and a material beating member, the material beating support frame is fixedly arranged on the vacuum plate, a material beating mounting seat is fixedly connected on the material beating support frame, the material beating member is arranged on the material beating mounting seat in a lifting manner, the material beating member is arranged between two adjacent vacuum belts, the pole pieces on the vacuum belts are used for falling off, and the material beating driving assembly is used for driving the lifting movement of the material beating member.

In the above structure, the material driving assembly comprises a material motor, an eccentric shaft and a bearing, wherein the bearing is arranged on the eccentric shaft, the material motor is connected to the eccentric shaft, a material supporting plate is arranged on the material mounting seat in a sliding manner, a rotating hole is formed in the material supporting plate, the bearing is rotationally connected to the rotating hole, a material connecting plate is connected to the material supporting plate, three material beating pieces are fixed on the material connecting plate, and the three material beating pieces can respectively lift between two adjacent vacuum belts.

The utility model has the advantages that the cantilever type fixed lifting mechanism is arranged, when maintenance is needed, the fixed lifting mechanism lifts the belt conveying mechanism, the lifting height is large, the structure maintenance and replacement are quick and convenient, the whole structure support reliability is high, the pole piece is conveyed in a vacuum negative pressure mode, the pole piece can be effectively prevented from being scratched by the conveying structure in the conveying process, and the adsorption reliability is high.

Drawings

The utility model will be further described with reference to the drawings and examples.

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

FIG. 2 is a schematic rear view of the belt conveyor of the present utility model;

FIG. 3 is a schematic view of a fixed lifting mechanism of the present utility model;

FIG. 4 is a schematic view of the automatic tensioning mechanism of the present utility model;

FIG. 5 is a schematic view of the structure of the automatic material beating mechanism of the utility model;

Fig. 6 is a schematic diagram of the connection structure of the deviation correcting roller of the present utility model.

Reference numerals:

1. A belt conveying mechanism; 11, a power seat, 12, a conveying driving assembly, 121, a servo motor, 122, a driving roller, 123, a compression roller, 13, a guide roller, 14, a vacuum belt, 141 and a guide plate;

2. A vacuum chamber assembly; 21 parts of vacuum plates, 211 parts of deviation correcting mounting plates, 212 parts of deviation correcting rollers, 213 parts of regulating blocks, 22 parts of vacuum pipelines;

3. The fixed lifting mechanism, 31, a lifting mounting seat, 311, a first connecting plate, 312, a second connecting plate, 313, a first linear slide rail, 3131, a first sliding block, 314, a second linear slide rail, 32, a lifting driving assembly, 321, a first lifting cylinder, 322, a second lifting cylinder, 33, a hydraulic buffer, 331, a buffer mounting block, 34, a supporting and adjusting assembly, 341, a supporting and fixing rod, 342, a supporting and adjusting rod, 343 and a fixing nut;

4. An automatic tensioning mechanism; 41, a tensioning mounting seat, 411, a tensioning fixing seat, 4111, a tensioning guide rail, 412, a tensioning connecting plate, 4121, a tensioning sliding block, 42, a tensioning roller, 43, a tensioning cylinder, 44, a guiding idler roller, 45 and a tensioning supporting plate;

5. An automatic material beating mechanism; 51, a material beating support frame, 511, a material beating support plate, 512, a support column, 513, a fixed block, 52, a material beating driving component, 521, a material beating motor, 522, an eccentric shaft, 523, a bearing, 53, a material beating piece, 531, a material beating rod, 532, a material beating head, 54, a material beating mounting seat, 541, a material beating support plate, 5411 and a rotation hole;

6. pole pieces.

Detailed Description

The utility model will be further described with reference to fig. 1-6.

The conception, specific structure, and technical effects produced by the present utility model will be clearly and completely described below with reference to the embodiments and the drawings to fully understand the objects, features, and effects of the present utility model. It is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and that other embodiments obtained by those skilled in the art without inventive effort are within the scope of the present utility model based on the embodiments of the present utility model. In addition, all the coupling/connection relationships referred to in the patent are not direct connection of the single-finger members, but rather, it means that a better coupling structure can be formed by adding or subtracting coupling aids depending on the specific implementation. The technical features in the utility model can be interactively combined on the premise of no contradiction and conflict.

Referring to fig. 1 to 6, the utility model provides a reverse-hanging vacuum belt 14 line, which is applied to a cutting and stacking integrated machine and can be used for conveying a pole piece 6 in the production process of a longer electric core. It comprises a belt conveying mechanism 1, a fixed lifting mechanism 3 and a vacuum cavity assembly 2. The belt conveying mechanism 1 comprises a power seat 11, a vacuum belt 14, guide rollers 13 and a conveying driving assembly 12, wherein the guide rollers 13 are arranged on a conveying path of the vacuum belt 14 to guide the vacuum belt 14, the vacuum belt 14 is wound on a steering roller, and the conveying driving assembly 12 is arranged on the power seat 11 and used for driving the vacuum belt 14 to rotate. The fixed lifting mechanism 3 is used for supporting and lifting the belt conveying mechanism 1, and the fixed lifting mechanism 3 supports the belt conveying mechanism 1 when the pole piece 6 is conveyed normally, and is started to lift the equipment when the equipment is required to be maintained, so that the equipment is maintained. The vacuum chamber assembly 2 is used for generating negative pressure, and comprises a vacuum plate 21 and a plurality of vacuum pipes 22, wherein the vacuum plate 21 is suspended below the power seat 11, and the vacuum pipes 22 are arranged on two opposite sides of the vacuum plate 21. The vacuum pipeline 22 is connected to the integrated fan, and the integrated fan forms negative pressure to the vacuum plate 21 through the vacuum pipeline 22, and the through hole is seted up on the vacuum belt 14, and the vacuum belt 14 laminating vacuum plate 21 is positive for the negative pressure acts on pole piece 6, and then makes pole piece 6 adsorb in the vacuum belt 14.

In the present embodiment, the joint direction of the vacuum pipe 22 provided inside the vacuum plate 21 is downward, and the joint direction of the vacuum pipe 22 provided outside the vacuum plate 21 is upward. The vacuum pipeline 22 connector on the inner side is downwards arranged, so that the maintenance difficulty of the vacuum pipeline 22 is reduced, and the vacuum pipeline 22 on the inner side is convenient to maintain when the belt conveying mechanism 1 is lifted by the fixed lifting mechanism 3.

Referring to fig. 1 and 3, the fixed lifting mechanism 3 is configured to support and lift the belt conveying mechanism 1, specifically, the fixed lifting mechanism 3 includes a lifting mounting seat 31 and a lifting driving assembly 32, the power seat 11 is connected to the lifting mounting seat 31, and the power seat 11 can move up and down in the lifting mounting seat 31 along a vertical direction, that is, the power seat 11 is configured to be liftable and liftable, the lifting driving assembly 32 includes a lifting cylinder one 321, and the lifting cylinder one 321 is configured to drive the power seat 11 to be lifted and lowered in the lifting mounting seat 31.

Further, the lifting installation seat 31 is slidably connected with a first connection plate 311, the power seat 11 is fixedly connected with the first connection plate 311, and a piston rod of the first lifting cylinder 321 is fixedly connected with the first connection plate 311 for driving the first connection plate 311 to slide in the lifting installation seat 31 along the vertical direction.

In this embodiment, a first linear sliding rail 313 extending along the vertical direction is fixedly connected to the lifting mounting seat 31, a first sliding block 3131 is slidingly connected to the first linear sliding rail 313, the first sliding block 3131 is fixedly connected to the first connecting plate 311, the first lifting cylinder 321 is fixedly mounted on the lifting mounting seat 31 and located below the first connecting plate 311, a lifting head is fixedly arranged on one side of the first connecting plate 311, which is close to the first lifting cylinder 321, and a piston rod of the first lifting cylinder 321 is fixedly connected to the lifting head. When the piston rod of the lifting cylinder I321 is retracted, the connecting plate I311 is driven to slide downwards along the first slide rail, the power seat 11 is driven to descend to the lower position, and the pole piece 6 can be conveyed normally.

Further, the lifting installation seat 31 is close to the first 311 side fixedly connected with oil buffer 33, the first 311 side fixedly connected with buffer installation block 331, the buffer installation block 331 is connected with the oil buffer 33, lifting movement of the first 321 lifting cylinder can be guaranteed to be carried out stably through oil buffer and limiting.

Referring to fig. 1 and 3, the fixed lifting mechanism 3 further includes a support adjustment assembly 34, wherein a plurality of groups of support adjustment assemblies 34 are disposed on one side of the belt conveying mechanism 1 opposite to the lifting driving assembly 32, and the support adjustment assemblies 34 are disposed below the vacuum chamber assembly 2 for supporting the vacuum chamber assembly 2. The support adjusting assembly 34 includes a support adjusting rod 342 and a support fixing rod 341, the support adjusting rod 342 is screwed to the support fixing rod 341, the support fixing rod 341 is disposed below the support adjusting rod 342, and one end of the support adjusting rod 342 away from the support fixing rod 341 abuts against the vacuum plate 21 to support the vacuum plate 21. The support adjustment lever 342 can be lifted to the support fixing lever 341 by rotating the support adjustment lever 342, thereby achieving the adjustment of the height of the support adjustment assembly 34. A fixing nut 343 is further connected between the support adjusting rod 342 and the support fixing rod 341 in a threaded manner, and the fixing nut 343 is used for tightening and fixing the support adjusting rod 342 and the support fixing rod 341, so that the connection strength of the support adjusting assembly 34 is further ensured. In this embodiment, two sets of support adjustment assemblies 34 are provided, and the two sets of support adjustment assemblies 34 are provided at the front end and the rear end of the vacuum plate 21 in the conveying direction, and support the vacuum plate 21 back and forth, so that the overall stability of the mechanism is ensured.

Referring to fig. 1 and 4, the inverted vacuum belt 14 line further includes an automatic tensioning mechanism 4, the automatic tensioning mechanism 4 being configured to adjust the degree of tensioning of the vacuum belt 14. The automatic tensioning mechanism 4 comprises a tensioning installation seat 41, a tensioning roller 42 and a tensioning air cylinder 43, wherein a tensioning fixing seat 411 is fixedly connected to the tensioning installation seat 41, the tensioning air cylinder 43 is fixedly installed on the tensioning fixing seat 411, the tensioning roller 42 is arranged on the tensioning fixing seat 411 in a lifting mode along the vertical direction, the tensioning air cylinder 43 is used for driving the tensioning roller 42 to lift, and the vacuum belt 14 is wound on the tensioning roller 42. Specifically, the tensioning fixing seat 411 is slidably connected with a tensioning connection plate 412, the tensioning roller 42 is mounted on the tensioning connection plate 412, and a piston rod of the tensioning cylinder 43 is fixedly connected to the tensioning connection plate 412.

In the present embodiment, a tensioning rail 4111 extending in the vertical direction is fixedly connected to the tensioning fixing base 411, a tensioning slider 4121 is fixedly connected to the tensioning connecting plate 412, and the tensioning slider 4121 is slidably connected to the tensioning rail 4111. When the piston rod of the tensioning cylinder 43 is extended, the tensioning connection plate 412 is driven to vertically move downwards, the tensioning roller 42 is driven to vertically move downwards, the vacuum belt 14 is gradually relaxed in the process, and when the piston rod of the tensioning cylinder 43 is retracted, the tensioning roller 42 is driven to vertically move upwards, and the vacuum belt 14 is gradually tensioned in the process.

Further, the automatic tensioning mechanism 4 further comprises a guide idler 44 and a tensioning support plate 45, the guide idler 44 is fixedly mounted on the tensioning mounting seat 41, the two groups of guide idlers 44 are symmetrically arranged on two opposite sides of the tensioning roller 42, the vacuum belt 14 is wound on the guide idlers 44, the guide idler 44 supports the vacuum belt 14, and the tensioning support plate 45 is fixedly mounted on the vacuum plate 21 and fixedly connected with the tensioning fixing seat 411 so as to ensure connection stability between the automatic tensioning mechanism 4 and the vacuum plate 21.

Further, the tensioning mount 41 is slidably disposed on the lifting mount 31 along the vertical direction, and the lifting driving assembly 32 further includes a second lifting cylinder 322, where the second lifting cylinder 322 is configured to drive the tensioning mount 41 to lift on the lifting mount 31. Specifically, the lifting installation seat 31 is slidably connected with the second connection plate 312, the tensioning installation seat 41 is fixedly connected with the second connection plate 312, the lifting air cylinder two 322 is fixedly arranged on the lifting installation seat 31 and located below the second connection plate 312, and a piston rod of the lifting air cylinder two 322 is fixedly connected with the second connection plate 312 and used for driving the second connection plate 312 to slide in the lifting installation seat 31 along the vertical direction so as to drive the tensioning installation seat 41 to perform lifting motion. The automatic tensioning mechanism 4 is arranged, so that the tensioning and loosening of the vacuum belt 14 can be adjusted, and the vacuum belt 14 can be conveniently disassembled and assembled during maintenance.

In this embodiment, a second linear sliding rail 314 extending along the vertical direction is fixedly connected to the lifting mounting seat 31, a second sliding block is slidably connected to the second linear sliding rail 314, the second sliding block is fixedly connected to a second connecting plate 312, a lifting head is fixedly arranged on one side of the second connecting plate 312, which is close to the second lifting cylinder 322, and a piston rod of the second lifting cylinder 322 is fixedly connected to the lifting head. When the piston rod of the second lifting cylinder 322 stretches out, the second connecting plate 312 is driven to move upwards along the second sliding rail, the tensioning installation seat 41 is driven to lift upwards, and further the integral lifting of the automatic tensioning mechanism 4 is achieved, and when the piston rod of the second lifting cylinder 322 retracts, the second connecting plate 312 is driven to slide downwards along the second sliding rail, and the tensioning installation seat 41 is driven to descend.

Further, in order to ensure stable lifting of the automatic tensioning mechanism 4, the hydraulic buffer 33 is fixedly connected to one side of the lifting installation seat 31, which is close to the second connection plate 312, and the buffer installation block 331 is correspondingly fixedly connected to the second connection plate 312, and the buffer installation block 331 is connected with the hydraulic buffer 33.

In practical application, the lifting cylinder I321 and the lifting cylinder II 322 are driven to operate simultaneously, and piston rods of the two cylinders extend and retract synchronously, so that synchronous vertical lifting of the connecting plate I311 and the connecting plate II 312 is realized, and further lifting of the whole equipment is realized. The lifting of the automatic tensioning mechanism 4 and the belt conveying mechanism 1 is driven by different driving pieces, so that the weight of the overall heavy equipment is shared, and the lifting stability and the service life of the equipment are guaranteed.

Referring to fig. 1 and 2, in the present embodiment, four vacuum belts 14 are provided, the four vacuum belts 14 are disposed on the vacuum plate 21 side by side, a guide plate 141 is disposed between adjacent vacuum belts 14, the guide plate 141 is fixedly connected to the side of the vacuum plate 21 facing the pole piece 6, and one end of the guide plate 141 away from the vacuum plate 21 (i.e. the top of the guide plate 141) is flush with the surface of the vacuum belt 14. The guide plates 141 are used to fill the gap between adjacent vacuum belts 14 and the height difference between the vacuum belts 14 and the vacuum plates 21 to ensure that the pole pieces 6 can be transported smoothly.

Referring to fig. 1 and 6, further, the end of the vacuum plate 21 in the conveying direction of the pole piece 6 is fixedly connected with a rectifying mounting plate 211, four rectifying rollers 212 corresponding to the vacuum belts 14 one by one are arranged on the rectifying mounting plate 211, the vacuum belts 14 are wound on the rectifying rollers 212, two ends of each rectifying roller 212 are provided with adjusting blocks 213, the adjusting blocks 213 are fixedly connected with the rectifying mounting plate 211, and the vacuum belts 14 are located between the adjusting blocks 213 on two sides of the corresponding rectifying roller 212. The regulating block 213 limits the vacuum belts 14, so that the vacuum belts 14 cannot deviate from the deviation correcting rollers 212 in the conveying process, four groups of deviation correcting rollers 212 and regulating blocks 213 are arranged to limit and correct the four vacuum belts 14 one by one, and independent deviation correction of each vacuum belt 14 is realized.

Referring to fig. 1 and 2, further, the conveying driving assembly 12 includes a servo motor 121 and a driving roller 122, the servo motor 121 is fixedly installed on the power seat 11, the servo motor 121 is connected with a speed reducer, the speed reducer is connected to the driving roller 122, the vacuum belt 14 is wound on the driving roller 122, and the servo motor 121 drives the driving roller 122 to rotate so as to drive the vacuum belt 14 to rotate, so that conveying of the pole piece 6 is achieved.

Further, the conveying driving assembly 12 further comprises two groups of press rollers 123, the two groups of press rollers 123 are symmetrically arranged on two opposite sides of the driving roller 122, the vacuum belt 14 is wound from the lower side of the press rollers 123, the two groups of press rollers 123 are arranged on the power seat 11, the press rollers 123 are used for compressing the vacuum belt 14, the two groups of press rollers 123 enable the vacuum belt 14 to form a larger wrap angle, and the possibility of slipping of the vacuum belt 14 in the conveying process is reduced.

Referring to fig. 1 and 5, the inverted vacuum belt 14 line further includes an automatic material-beating mechanism 5, and the automatic material-beating mechanism 5 is used for beating the bad pole piece 6 on the vacuum belt 14. The automatic material beating mechanism 5 comprises a material beating support frame 51, a material beating driving assembly 52 and a material beating piece 53, wherein the material beating support frame 51 is fixedly arranged on the vacuum plate 21, the material beating support frame 51 is fixedly connected with a material beating installation seat 54, the material beating piece 53 is arranged on the material beating installation seat 54 and can be lifted and arranged on the material beating installation seat 54, the material beating piece 53 is positioned between two adjacent vacuum belts 14 and used for enabling pole pieces 6 on the vacuum belts 14 to fall off, and the material beating driving assembly 52 is used for driving the material beating piece 53 to lift.

In this embodiment, the material supporting frame 51 includes a material supporting plate 511, a fixing block 513 and supporting columns 512 disposed at four corners of the material supporting plate 511, the fixing block 513 is fixedly connected to one end of the supporting column 512 away from the material supporting plate 511, and the fixing block 513 is fixedly disposed on the vacuum plate 21, and the material mounting seat 54 is fixedly connected to the material supporting plate 511.

Further, the beating driving assembly 52 includes a beating motor 521, an eccentric shaft 522 and a bearing 523, the beating motor 521 is fixedly connected to the beating mounting seat 54, the eccentric shaft 522 is fixedly connected to an output shaft of the beating motor 521, and the bearing 523 is disposed at one end of the eccentric shaft 522 far away from the beating motor 521. The material beating mounting seat 54 is connected with a material beating supporting plate 541 in a sliding manner, a rotating hole 5411 is formed in the material beating supporting plate 541, a bearing 523 is connected to the rotating hole 5411 in a rotating manner, a material beating connecting plate is connected to the material beating supporting plate 541, three material beating pieces 53 are fixedly connected to the material beating connecting plate, and the three material beating pieces 53 respectively correspond to three gaps between the adjacent vacuum belts 14. When the material beating motor 521 is driven, the eccentric shaft 522 is driven to rotate, the bearing 523 rotates along with the eccentric shaft 522, the bearing 523 rotates in the rotating hole 5411 to drive the material beating support plate 541 to vertically slide in the material beating mounting seat 54, lifting of the material beating piece 53 is achieved, when the material beating piece 53 descends, the pole piece 6 on the vacuum belt 14 can be beaten, and then the pole piece 6 is beaten off from the vacuum belt 14.

In this embodiment, the material beating member 53 includes a material beating rod 531 and a material beating head 532, one end of the material beating rod 531 is fixedly connected to the material beating connection plate, and the material beating head 532 is fixedly connected to one end of the material beating rod 531 away from the material beating connection plate. The beating head 532 may be made of rubber or other material, so as to avoid scratching the pole piece 6 when beating the pole piece 6.

In the present embodiment, two sets of automatic material beating mechanisms 5 are provided, and the two sets of automatic material beating mechanisms 5 are provided back and forth in the conveying direction of the pole pieces 6.

While the preferred embodiment of the present utility model has been described in detail, the present utility model is not limited to the embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present utility model, and the equivalent modifications or substitutions are included in the scope of the present utility model as defined in the appended claims.

Claims (10)

1. The inverted-hanging vacuum belt line is characterized by comprising a belt conveying mechanism, a fixed lifting mechanism and a vacuum cavity assembly, wherein the belt conveying mechanism comprises a power seat, a conveying driving assembly, guide rollers and a vacuum belt, the conveying driving assembly, the guide rollers and the vacuum belt are arranged on the power seat, the guide rollers are arranged on a vacuum belt conveying path, the vacuum belt is wound on the guide rollers, and the conveying driving assembly is used for driving the vacuum belt to rotate;

The vacuum cavity assembly comprises a vacuum plate and a plurality of vacuum pipelines, the vacuum plate is mounted below the power seat in a hanging manner, and the vacuum pipelines are arranged on two opposite sides of the vacuum plate;

The fixed lifting mechanism is used for supporting and lifting the belt conveying mechanism, the fixed lifting mechanism comprises a lifting installation seat and a lifting driving assembly, the power seat is slidably connected with the lifting installation seat along the vertical direction, and the lifting driving assembly is used for driving the power seat to lift.

2. The inverted lift vacuum belt line of claim 1, wherein the lift driving assembly comprises a first lift cylinder, a first connecting plate is connected to the first lift mounting seat in a sliding manner, the power seat is fixedly connected to the first connecting plate, a piston rod of the first lift cylinder is fixedly connected to the first connecting plate and used for driving the first connecting plate to slide on the first lift mounting seat in the vertical direction, an oil buffer is fixedly connected to the first lift mounting seat, a buffer mounting block is fixedly connected to the first connecting plate, and the buffer mounting block is connected with the oil buffer.

3. The inverted-lift vacuum belt line as in claim 2, further comprising an automatic tensioning mechanism, wherein the automatic tensioning mechanism comprises a tensioning installation seat, a tensioning roller and a tensioning cylinder, the tensioning installation seat is slidably connected to the lifting installation seat in the vertical direction, a tensioning fixing seat is fixedly connected to the tensioning installation seat, the tensioning cylinder is fixedly connected to the tensioning fixing seat, the tensioning roller is arranged on the tensioning fixing seat in the vertical direction in a liftable manner, the tensioning cylinder is used for driving the tensioning roller to lift, and the vacuum belt is wound around the tensioning roller.

4. The inverted lift vacuum belt line of claim 3, wherein the lift driving assembly further comprises a second lift cylinder, the second lift mounting seat is slidably connected with a second connection plate, the tensioning mounting seat is fixedly connected with the second connection plate, and a piston rod of the second lift cylinder is fixedly connected with the second connection plate to drive the second connection plate to slide on the second lift mounting seat in the vertical direction.

5. The inverted suspension vacuum belt line as in claim 3, wherein the automatic tensioning mechanism further comprises a guide idler and a tensioning support plate, the guide idler is fixedly connected to the tensioning installation seat, two groups of guide idlers are symmetrically arranged on two sides of the tensioning roller, the guide idler is used for supporting the vacuum belt, and the tensioning support plate is fixedly arranged on the vacuum plate and fixedly connected with the tensioning fixing seat.

6. The inverted crane vacuum belt line as in claim 1, wherein the fixed lifting mechanism further comprises a plurality of groups of support adjusting assemblies arranged below the vacuum cavity assembly, the support adjusting assemblies are arranged on one side of the belt conveying mechanism opposite to the lifting driving assembly, the support adjusting assemblies comprise support adjusting rods and support fixing rods, the support adjusting rods are in threaded connection with the support fixing rods, and one ends, far away from the support fixing rods, of the support adjusting rods are abutted to the vacuum plate.

7. The inverted crane vacuum belt line according to claim 1, wherein four vacuum belts are arranged side by side, guide plates are arranged between adjacent vacuum belts, and the tops of the guide plates are level with the surfaces of the vacuum belts;

The vacuum plate end part is fixedly connected with a correction mounting plate, correction rollers which are in one-to-one correspondence with the four vacuum belts are arranged on the correction mounting plate, two ends of each correction roller are connected with adjusting blocks, and the adjusting blocks are fixedly connected with the correction mounting plate.

8. The inverted crane vacuum belt line according to claim 1, wherein the conveying driving assembly comprises a servo motor and a driving roller, the servo motor is fixedly arranged on the power seat, the vacuum belt is wound on the driving roller, the output end of the servo motor is connected with a speed reducer, and the speed reducer is connected with the driving roller and is used for driving the driving roller to rotate so as to drive the vacuum belt to rotate.

9. The inverted crane vacuum belt line as set forth in claim 7, further comprising an automatic material beating mechanism, wherein the automatic material beating mechanism comprises a material beating support frame, a material beating driving assembly and a material beating member, the material beating support frame is fixedly installed on the vacuum plate, the material beating support frame is fixedly connected with a material beating installation seat, the material beating member is arranged on the material beating installation seat in a lifting manner, the material beating member is arranged between two adjacent vacuum belts to enable pole pieces on the vacuum belts to fall off, and the material beating driving assembly is used for driving the material beating member to lift.

10. The inverted crane vacuum belt line according to claim 9, wherein the material driving assembly comprises a material motor, an eccentric shaft and a bearing, the bearing is mounted on the eccentric shaft, the material motor is connected to the eccentric shaft, a material supporting plate is slidably arranged on the material mounting seat, a rotating hole is formed in the material supporting plate, the bearing is rotatably connected to the rotating hole, a material connecting plate is connected to the material supporting plate, three material beating pieces are fixed on the material connecting plate, and the three material beating pieces can be lifted between two adjacent vacuum belts respectively.