CN218087304U - Pole piece caching device - Google Patents

Abstract

The utility model relates to a pole piece caching device, which comprises a first fixing plate, a transmission mechanism, an adjusting mechanism and a driving mechanism, wherein the first fixing plate comprises a first side and a second side which are opposite; the transmission mechanism is arranged on the first side and comprises a plurality of movable rollers and a plurality of fixed rollers which are matched with each other to form a pole piece winding transmission channel; the adjusting mechanism is arranged on the second side and comprises a second fixing plate and a belt, one end of the belt is fixed on the second fixing plate, and the other end of the belt extends to the first side around the top of the first fixing plate after being wound on the second fixing plate and is connected with the movable roller so as to provide tension for the movable roller; the driving mechanism is arranged on the second fixing plate and used for adjusting the winding length of the belt so as to adjust the extending length of the belt on the first side, and therefore the distance between the moving roller and the fixed roller is adjusted. The utility model discloses a pole piece caching device has simple structure, moves stable advantage.

Description

Pole piece caching device

Technical Field

The utility model relates to a lithium battery pole piece production facility's technical field especially relates to a pole piece buffer memory device.

Background

In the production process of the lithium battery, pole pieces in the battery core need to go through a plurality of different processes and steps, and the transmission speeds of the pole pieces required in the different processes are different, so that the different transmission speeds of the front and rear pole pieces can cause the loosening of the pole pieces or the tearing of the pole pieces due to the pulling of the pole pieces in the different processes. Therefore, a buffer device is required to be arranged between the processes with different speeds, so that the speed difference of the processes before and after is balanced, and the tension of pole piece transmission is kept.

However, the existing pole piece caching device uses a gravity mechanism and a driving mechanism to match to enable the movable roller to move up and down for adjustment, or uses a motor to directly drive a transmission belt to drive the movable roller, and has the defects of complex structure and unstable operation.

SUMMERY OF THE UTILITY MODEL

Based on this, the utility model aims to provide a pole piece buffer memory device, it has simple structure, moves stable advantage.

The utility model discloses a realize through following scheme:

a pole piece caching apparatus, comprising:

a first fixation plate including opposing first and second sides;

the transmission mechanism is arranged on the first side and comprises a plurality of movable rollers and a plurality of fixed rollers, and the movable rollers and the fixed rollers are matched to form a pole piece winding transmission channel;

the adjusting mechanism is arranged on the second side and comprises a second fixing plate and a belt, one end of the belt is fixed on the second fixing plate, and the other end of the belt winds the second fixing plate, extends to the first side of the first fixing plate by bypassing the top of the first fixing plate, is connected with the moving roller and provides tension for the moving roller;

the driving mechanism is arranged on the second fixing plate and used for adjusting the winding length of the belt so as to adjust the extending length of the belt on the first side, and therefore the distance between the moving roller and the fixed roller is adjusted.

A pole piece memory device, walk around the top of first fixed plate through the belt that sets up guiding mechanism, then the coiling length of belt on the control guiding mechanism adjusts the distance of removing between roller and the fixed roller, its structural design is simple, and the operation process is stable.

Further, the conveying mechanism comprises a first linear guide rail and a sliding plate, the first linear guide rail is vertically arranged on a first side of the first fixing plate, and the sliding plate is movably arranged on the first linear guide rail;

the plurality of moving rollers are fixedly connected to the sliding plate at horizontal intervals. By arranging the movable sliding plate, the distance between the movable roller and the fixed roller can be adjusted by moving the sliding plate, and the effect of caching the pole pieces is achieved.

Further, the moving roller is arranged at the upper part of the first linear guide rail, and the fixed roller is fixedly arranged at the lower part of the first linear guide rail. The movable roller is arranged at the upper part, the fixed roller is arranged at the lower part, and a height difference exists between the movable roller and the fixed roller, so that the pole piece is transmitted between the movable roller and the fixed roller.

Furthermore, the transmission mechanism further comprises a groove-shaped photoelectric sensor, wherein the groove-shaped photoelectric sensor is arranged on the edge of the first fixing plate and corresponds to the upper end and the lower end of the first linear guide rail. The groove-type photoelectric sensor detects the moving position of the moving roller.

Furthermore, the adjusting mechanism further comprises a second linear guide rail, a buffer sliding seat, a first idler wheel set and a second idler wheel set, the second fixing plate is vertically and fixedly arranged relative to the first fixing plate, the second linear guide rail is vertically arranged on the second fixing plate, and the buffer sliding seat is movably arranged on the second linear guide rail;

the belt is wound and tensioned between the first idler pulley group and the second idler pulley group, wherein the first idler pulley group is arranged on the second fixing plate, the second idler pulley group is arranged on the buffer sliding seat, and a height difference exists between the first idler pulley group and the second idler pulley group;

the driving mechanism is fixedly connected with the buffer sliding seat and used for adjusting the height of the buffer sliding seat so as to adjust the winding length of the belt. The adjusting mechanism enables the belt to be wound between the two groups of idle wheels by arranging the first idle wheel group and the second idle wheel group, and the distance between the two groups of idle wheels can be adjusted by the buffer sliding seat.

Further, the first idler pulley group comprises a plurality of first idler pulleys for belt, and the plurality of first idler pulleys for belt are arranged on the upper part of the second fixing plate at equal intervals; the second idler pulley set comprises a plurality of second idler pulleys for belts, and the plurality of second idler pulleys for belts are arranged on the buffer sliding seat at the lower part of the second fixing plate at equal intervals; and the belt is sequentially wound up and down between the first belt idler pulley and the second belt idler pulley for tensioning. The belt idlers of the first idler pulley group are disposed on the upper portion of the second fixed plate, and the belt idlers of the second idler pulley group are disposed on the lower portion of the second fixed plate so that a height difference exists between the belt idlers and the second fixed plate, and the belt is wound in sequence between the belt idlers and the second fixed plate.

Furthermore, the adjusting mechanism further comprises a pulley-assisted wheel, a belt reversing wheel and a belt end pressing plate, the pulley-assisted wheel is arranged on the upper portion of the second side of the second fixing plate, the belt reversing wheel is arranged on the top of the first fixing plate, the belt end pressing plate is arranged on the sliding plate, and the other end of the belt passes through the pulley-assisted wheel and the belt reversing wheel after winding around the idler wheel for the belt and is fixedly connected with the sliding plate through the belt end pressing plate. The belt extends to the first side from the top that the second fixed plate was walked around first fixed plate through pulley-aid, belt switching-over wheel with the belt, and fixes belt and sliding plate through belt end clamp plate to provide pulling force for the sliding plate, adjust the position of sliding plate.

Further, actuating mechanism includes the cylinder, the cylinder is fixed to be set up the bottom of second fixed plate, the push rod of cylinder with buffer memory slide fixed connection. The buffer sliding seat is pushed to move by arranging the air cylinder, so that the distance between the first idler wheel set and the second idler wheel set on the adjusting mechanism is adjusted.

Further, actuating mechanism still includes linear encoder, linear encoder sets up the side of buffer memory slide, linear encoder with the cylinder is connected. And detecting the sliding distance of the buffer sliding seat by arranging a linear encoder.

Further, the driving mechanism further comprises a tension detection assembly and an electromagnetic proportional valve, the tension detection assembly is arranged on the pole pieces which enter and exit the transmission mechanism, the tension detection assembly is connected with the electromagnetic proportional valve, and air pressure is transmitted to the air cylinder through the electromagnetic proportional valve. The tension detection assembly can detect the tension of the pole piece in the transmission process, so that whether the buffer memory needs to be adjusted or not is calculated, the electromagnetic proportional valve is connected with the air cylinder, the air pressure of the air cylinder is controlled, and the position of the buffer memory sliding seat is adjusted.

An embodiment a pole piece memory device, set up including removing roller and fixed roll matched with pole piece transmission mechanism through one side at first fixed plate, and set up the guiding mechanism who is fixed with the belt at the opposite side of first fixed plate, and can be through the length that the adjustment belt convoluteed on the second fixed plate, adjust the belt in the length that removes roller one side, thereby the distance between roller and the fixed roll is removed in the regulation, under the condition of removing the roller and having realized pulling force support highly, still realized the distance adjustment between roller and the fixed roll removing, thereby be convenient for to the adjustment of the coiling distance of the pole piece of transmitting among the pole piece transmission mechanism, with the tensile force of adjustment pole piece.

Further, the embodiment of the utility model provides a still through set up first linear guide and sliding plate on first fixed plate, make to remove the roller and fix on the sliding plate, slidable adjustment removes the roller and fixes the distance between the roller, and set up second linear guide on the second fixed plate, the buffer memory slide, second idler group is fixed to be set up on the buffer memory slide, can slide on second linear guide, the belt is after convoluteing between first idler group and second idler group, through the booster wheel, belt reversing wheel and belt end clamp plate are walked around opposite side and sliding plate fixed connection from the top of adjustment mechanism through first fixed plate to the belt, then detect the tension of pole piece through setting up tension detection component after, through the atmospheric pressure of electromagnetic proportional valve adjustment input cylinder, and then adjust the buffer memory slide and adjust the distance of first idler group and second idler group, thereby adjust the coiling length of belt, the pulling or the release of belt, realize that the adjustment moves the distance of roller and fixed roller, accomplish the tensile force adjustment of pole piece.

For a better understanding and an implementation, the present invention is described in detail below with reference to the accompanying drawings.

Drawings

Fig. 1 is a rear view structural diagram of a pole piece buffer device according to an embodiment of the present invention;

fig. 2 is a rear perspective view of a pole piece buffer device according to an embodiment of the present invention;

fig. 3 is a side view structural diagram of a pole piece buffer device according to an embodiment of the present invention;

fig. 4 is a front perspective view of a pole piece buffer device according to an embodiment of the present invention.

Reference numerals: the device comprises a first fixing plate 100, a first side 110, a second side 120, a transmission mechanism 200, a first linear guide rail 210, a sliding plate 220, a moving roller 230, a fixed roller 240, a groove type photoelectric sensor 250, an adjusting mechanism 300, a belt 310, a second fixing plate 320, a second linear guide rail 330, a buffer sliding seat 340, a first idler pulley group 350, a second idler pulley group 360, a belt end fixing plate 370, a first belt idler pulley 351, a second belt idler pulley 361, a belt end pressing plate 301, a belt reversing wheel 302, a pulley wheel 303, a driving mechanism 400, an air cylinder 410, a linear encoder 420 and a pole piece 500.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

To solve the technical problem in the background art, an embodiment of the present invention provides a pole piece buffering device, as shown in fig. 1 to 4, including a first fixing plate 100, a transmission mechanism 200, an adjustment mechanism 300, and a driving mechanism 400. The first fixing plate 100 includes opposite first and second sides 110 and 120. Preferably, the first fixing plate 100 is a rectangular plate fixedly disposed vertically.

The transmission mechanism 200 is disposed on the first side 110 of the first fixing plate 100, the transmission mechanism 200 includes a plurality of moving rollers 230 and a plurality of fixed rollers 240, the transmission mechanism 200 is used for winding and transmitting the pole piece 500, the pole piece 500 is alternately wound between the moving rollers 230 and the fixed rollers 240 and then transmitted to a subsequent process, wherein the moving rollers 230 can move towards or away from the fixed rollers 240, so that the winding distance of the pole piece 500 between the moving rollers 230 and the fixed rollers 240 is increased or decreased to adjust the tension of the pole piece 500, wherein the moving rollers 230 and the fixed rollers 240 can be distributed up and down, the moving rollers 230 can be above or below the fixed rollers 240, and the tension transmitted by the pole piece is adjusted after the height of the moving rollers 230 is adjusted.

The adjusting mechanism 300 is disposed on the second side 120 of the first fixing plate 100, the adjusting mechanism 300 includes a belt 310 and a second fixing plate 320, one end of the belt 310 is fixed on the second fixing plate 320, and the other end of the belt 310 extends to the first side 110 of the first fixing plate 100 around the top of the first fixing plate 100 after being wound on the second fixing plate 320, and is connected to the moving roller 230 to provide an upward pulling force for the moving roller 230. The driving mechanism 400 is fixedly provided on the second fixing plate 320 for adjusting a winding length of the belt 310 to adjust a length of the belt 310 extending on the first side 110, thereby adjusting a distance between the moving roller 230 and the fixed roller 240. The belt 310 may be wound around the second fixing plate 320 by a winding method between a plurality of pulleys, and the driving mechanism 400 may adjust the winding length of the belt 310 by adjusting the distance between the pulleys.

In a preferred embodiment, as shown in fig. 2, the transport mechanism 200 further comprises a first linear guide rail 210 and a sliding plate 220. The first linear guide 210 is vertically disposed on the first side 110 of the first fixing plate 100, and the sliding plate 220 is movably mounted on the first linear guide 210 and can vertically slide on the first linear guide 210. The sliding plate 220 is disposed at an upper portion of the first linear guide 210, and a plurality of moving-over rollers 230 are fixedly disposed at intervals on the sliding plate 220. A plurality of fixed rollers 240 are fixedly provided at a lower portion of the first linear guide 210. That is, moving roller 230 is slidably disposed over fixed roller 240, and pole piece 500 is engaged between moving rollers 230 and fixed rollers 240 to form a pole piece winding transport path.

In a preferred embodiment, the transmission mechanism 200 further comprises a slot-type photosensor 250. The groove type photo sensor 250 is disposed at an edge of the first fixing plate 100 and corresponds to positions of upper and lower ends of the first linear guide 210 for detecting a position of the sliding plate 220.

In a preferred embodiment, as shown in fig. 3 and 4, the adjustment mechanism 300 further includes a second linear guide 330, a buffer slide 340, a first idler pulley set 350, a second idler pulley set 360, and a belt end fixing plate 370. The adjusting mechanism 300 is disposed on the second side 120 of the first fixing plate 100, the second fixing plate 320 is vertically and vertically fixed with respect to the first fixing plate 100, the second linear guide 330 is vertically disposed on the second fixing plate 320, and the buffer sliding base 340 is movably mounted on the second linear guide 330. The first idle pulley set 350 is disposed on the second fixing plate 320, the second idle pulley set 360 is disposed on the buffer sliding seat 340, a height difference exists between the first idle pulley set 350 and the second idle pulley set 360, and the belt 310 is wound and tensioned between the first idle pulley set 350 and the second idle pulley set 360. Specifically, the first idler pulley group 350 includes a plurality of first belt idler pulleys 351, and the plurality of first belt idler pulleys 351 are disposed at equal intervals on the upper portion of the second fixing plate 320; the second idle pulley group 360 includes a plurality of second belt idle pulleys 361, and the plurality of second belt idle pulleys 361 are disposed at equal intervals on the buffer slider 340 at the lower portion of the second fixing plate 320. The belt 310 is fixed to the second fixing plate 320 at a side away from the first fixing plate 100 by using a belt end fixing plate 370, and then the first belt idler 351 and the second belt idler 361 are sequentially wound up and down to be tensioned, and the distance between the first idler pulley set 350 and the second idler pulley set 360 can be adjusted by the movement of the buffer sliding base 340, so that the belt 310 can be tensioned differently.

In a preferred embodiment, the adjustment mechanism 300 further includes a pulley aid 303, a belt reversing pulley 302, and a belt end pressure plate 301. The auxiliary pulley 303 is provided at an upper portion of the second fixing plate 320 near an output position of the belt 310 to guide the belt 310 to the first fixing plate 100. A belt diverting pulley 302 is disposed on top of the first retaining plate 100 for diverting a belt 310 from the second side 120 of the first retaining plate 100 to the first side 110 of the first retaining plate 100. After the belt 310 is wound around the first side 110, the other end of the belt 310 is fixed to the sliding plate 220 by the belt end pressing plate 301. The belt 310 is output from the belt 310 idle pulley, passes through the auxiliary pulley 303 and the belt reversing pulley 302, and is fixedly connected to the sliding plate 220 by the belt end pressing plate 301, so that the movement of the belt 310 drives the sliding plate 220 to move up and down.

In a preferred embodiment, as shown in FIG. 4, the drive mechanism 400 includes a pneumatic cylinder 410 and a linear encoder 420. The cylinder 410 is fixedly disposed at the bottom of the second fixing plate 320. The push rod of the air cylinder 410 is fixedly connected with the buffer sliding seat 340, and is used for pushing the buffer sliding seat 340 to slide up and down, so as to adjust the distance between the first idle pulley set 350 and the second idle pulley set 360, and further adjust the tension of the belt 310. The linear encoder 420 is disposed on the side of the buffer slide 340 and connected to the cylinder 410, and is used for monitoring the position of the push rod of the cylinder 410 and feeding back the position in real time.

In a preferred embodiment, the drive mechanism 400 further includes a tension detection assembly (not shown) and a solenoid proportional valve (not shown). The tension detection assembly is arranged on the pole pieces 500 of the inlet transmission mechanism 200 and the outlet transmission mechanism 200 and is used for detecting the tension of the pole pieces 500 of the inlet transmission mechanism 200 and the outlet transmission mechanism 200. The tension detection assembly is also in signal connection with the electromagnetic proportional valve. The electromagnetic proportional valve is arranged on an air pressure input line of the air cylinder 410, and air pressure is transmitted to the air cylinder 410 after being adjusted by the electromagnetic proportional valve.

The embodiment of the utility model provides a pole piece buffer memory device, set up transmission device 200 through first side 110 at first fixed plate 100 for transmit pole piece 500. Specifically, a plurality of moving rollers 230 and a plurality of fixed rollers 240 are provided, and the moving rollers 230 are disposed on the sliding plate 220 and can vertically slide on the first linear guide 210, so as to adjust the distance between the moving rollers 230 and the fixed rollers 240, and further adjust the transmission tension of the pole piece 500. The second side 120 is provided with an adjusting mechanism 300, a second fixing plate 320 is fixedly arranged, a first idle pulley set 350 is arranged at the upper part of the second fixing plate 320, a second linear guide rail 330 is arranged at the lower part of the second fixing plate, the buffer sliding seat 340 can move on the second linear guide rail 330, the second idle pulley set 360 is fixedly arranged on the buffer sliding seat 340, one end of the belt 310 is fixed and then wound on the first belt idle pulley 351 and the second belt idle pulley 361, and the other end of the belt is output to the first side 110 to be fixedly connected with the sliding plate 220. The buffer sliding seat 340 is adjusted by fixedly arranging an air cylinder 410 at the bottom of the second fixing plate 320, a push rod of the air cylinder 410 is connected with the buffer sliding seat 340, the position of the buffer sliding seat 340 is adjusted by the air cylinder 410, and the position of the push rod of the air cylinder 410 is monitored in real time by arranging a linear encoder 420 to feed back and adjust in real time. Tension detection assemblies are arranged at the input end and the output end of the pole piece 500 for transmission, and tension of the pole piece 500 is detected. The tension detection assembly is connected with the electromagnetic proportional valve, and adjusts the air pressure input into the air cylinder 410 according to the tension of the pole piece 500, so as to adjust the position of the push rod, and then the push rod adjusts the position of the buffer sliding seat 340, so that the distance between the first idler pulley set 350 and the second idler pulley set 360 is changed, the belt 310 is tensioned and adjusted, so as to adjust the position of the sliding plate 220, and further tension and adjustment are performed on the pole piece 500.

The embodiment of the utility model provides a pole piece buffer memory device, pole piece 500 in transmission mechanism 200 need provide the pole piece to the back process, when accelerating conveying speed, the tension that tension detection subassembly detected pole piece 500 increases, and then control electromagnetism proportional valve adjusting cylinder 410, promote buffer memory slide 340 and upwards slide, the distance between first idler wheel group 350 and second idler wheel group 360 shortens, the belt 310 at first side 110 extends, sliding plate 220 slides down, shorten the distance between fixed roller 240 and the roller 230 of moving, the distance diminishes, conveying speed becomes fast; when the conveying speed needs to be reduced, the tension detection assembly detects that the tension of the pole piece 500 is reduced, and then the electromagnetic proportional valve adjusting cylinder 410 is controlled to drive the buffer sliding seat 340 to slide downwards, the distance between the first idler pulley group 350 and the second idler pulley group 360 is increased, the belt 310 on the first side 110 drives the sliding plate 220 to slide upwards, the distance between the fixed roller 240 and the movable roller 230 is also increased, the length of the buffered pole piece is increased, and the conveying speed is reduced. A pole piece memory device, it has simple structure, the stable advantage of operation.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that numerous changes and modifications can be made by those skilled in the art without departing from the spirit of the invention and it is intended that the invention encompass such changes and modifications as well.

Claims (10)

1. A pole piece caching device, comprising:

a first fixation plate including opposing first and second sides;

the transmission mechanism is arranged on the first side and comprises a plurality of moving rollers and a plurality of fixed rollers, and the moving rollers and the fixed rollers are matched to form a pole piece winding transmission channel;

the adjusting mechanism is arranged on the second side and comprises a second fixing plate and a belt, one end of the belt is fixed on the second fixing plate, and the other end of the belt extends to the first side of the first fixing plate by winding around the top of the first fixing plate after being wound on the second fixing plate and is connected with the moving roller to provide tension for the moving roller;

the driving mechanism is arranged on the second fixing plate and used for adjusting the winding length of the belt so as to adjust the extending length of the belt on the first side, and therefore the distance between the moving roller and the fixed roller is adjusted.

2. The pole piece caching apparatus of claim 1, wherein:

the transmission mechanism comprises a first linear guide rail and a sliding plate, the first linear guide rail is vertically arranged on the first side of the first fixing plate, and the sliding plate is movably arranged on the first linear guide rail;

the plurality of moving rollers are fixedly connected to the sliding plate at horizontal intervals.

3. The pole piece caching apparatus of claim 2, wherein:

the moving roller is arranged at the upper part of the first linear guide rail, and the fixed roller is fixedly arranged at the lower part of the first linear guide rail.

4. The pole piece caching apparatus of claim 3, wherein:

the transmission mechanism further comprises a groove-shaped photoelectric sensor, wherein the groove-shaped photoelectric sensor is arranged on the edge of the first fixing plate and corresponds to the positions of the upper end and the lower end of the first linear guide rail.

5. The pole piece caching apparatus of claim 2, wherein:

the adjusting mechanism further comprises a second linear guide rail, a buffer sliding seat, a first idler pulley group and a second idler pulley group, the second fixing plate is vertically and fixedly arranged relative to the first fixing plate, the second linear guide rail is vertically arranged on the second fixing plate, and the buffer sliding seat is movably arranged on the second linear guide rail;

the belt is wound and tensioned between the first idler pulley group and the second idler pulley group, wherein the first idler pulley group is arranged on the second fixing plate, the second idler pulley group is arranged on the buffer sliding seat, and a height difference exists between the first idler pulley group and the second idler pulley group;

the driving mechanism is fixedly connected with the buffer sliding seat and used for adjusting the height of the buffer sliding seat so as to adjust the winding length of the belt.

6. The pole piece caching apparatus of claim 5, wherein:

the first idler pulley group comprises a plurality of first idler pulleys for belt, and the plurality of first idler pulleys for belt are arranged on the upper part of the second fixing plate at equal intervals; the second idler pulley set comprises a plurality of second idler pulleys for belts, and the plurality of second idler pulleys for belts are arranged on the buffer sliding seat at the lower part of the second fixing plate at equal intervals; and the belt is sequentially wound and tensioned up and down between the first belt idler pulley and the second belt idler pulley.

7. The pole piece caching apparatus of claim 6, wherein:

the adjusting mechanism further comprises a pulley aid, a belt reversing wheel and a belt end pressing plate, wherein the pulley aid is arranged at the upper part of the second fixing plate close to the belt output position; the belt reversing wheel is arranged at the top of the first fixing plate, the belt end pressing plate is arranged on the sliding plate, and the other end of the belt is wound around the belt idler wheel and then passes through the auxiliary pulley and the belt reversing wheel to be fixedly connected with the sliding plate through the belt end pressing plate.

8. The pole piece caching apparatus of claim 7, wherein:

the driving mechanism comprises an air cylinder, the air cylinder is fixedly arranged at the bottom of the second fixing plate, and a push rod of the air cylinder is fixedly connected with the buffer sliding seat.

9. The pole piece caching apparatus of claim 8, wherein:

the driving mechanism further comprises a linear encoder, the linear encoder is arranged on the side face of the buffer sliding seat, and the linear encoder is connected with the air cylinder.

10. The pole piece caching apparatus of claim 9, wherein:

the driving mechanism further comprises a tension detection assembly and an electromagnetic proportional valve, the tension detection assembly is arranged on the pole pieces which enter and exit the transmission mechanism, the tension detection assembly is connected with the electromagnetic proportional valve, and air pressure is transmitted to the air cylinder through the electromagnetic proportional valve.

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