CN210854240U - Polar plate collecting device - Google Patents

Abstract

The utility model discloses a polar plate collecting device, which comprises a first conveying belt and a second conveying belt, wherein the input end of the second conveying belt is provided with a stacking mechanism for assisting polar plate stacking, the stacking mechanism comprises two supporting strips extending into the upper part of the second conveying belt from two sides, and the height of the supporting strips is not higher than the conveying surface of the first conveying belt; the receiving strip is divided into an upstream section for receiving the tail part of the connected polar plate and a downstream section for receiving the hanging lugs of the connected polar plate in the polar plate conveying direction, the distance between the upstream sections of the two receiving strips is smaller than the width between the two connecting strips of the connected polar plate, and the distance between the downstream sections of the two receiving strips is larger than the width between the two connecting strips of the connected polar plate and smaller than the width between the two hanging lugs of the connected polar plate. After the polar plate is thrown out from the first conveying belt, the polar plate is stacked on the second conveying belt after the carrying transition of the carrying strip, the falling impact force of the continuous polar plate is greatly reduced, and the phenomenon that the lead plaster is deformed after the continuous polar plate falls off and the quality of the polar plate is influenced due to the concave-convex plaster phenomenon is avoided.

Description

Polar plate collecting device

Technical Field

The utility model relates to a lead acid battery production technical field especially relates to a piece device is received to polar plate.

Background

The lead-acid storage battery belongs to a reversible direct-current power supply, and can convert chemical energy into electric energy and also convert the electric energy into chemical energy. The lead storage battery mainly comprises electrolyte, a battery jar and a polar group, wherein the electrolyte of the lead storage battery is sulfuric acid solution, the polar group mainly comprises a positive plate, a negative plate and a partition plate, and the partition plate mainly stores the electrolyte and serves as a gas channel for compounding oxygen to prevent active substances from falling off and prevent short circuit between the positive and negative electrodes.

In the production process of the polar plate, the polar plate is generally produced in a form of a connected polar plate and then is cut, the connected polar plate is generally provided with connecting strips on two sides, and the outer side of one end of each connecting strip is provided with a hanging lug which is used for hanging and placing the connected polar plate. The continuous plate is generally required to be stacked and collected after being coated by a coating machine.

The plate collecting mode is that after the polar plates are output by the plate coating machine, the polar plates are thrown down to the next-stage conveying belt to be received and stacked by one piece, after the polar plates are stacked to a certain number, the conveying belt moves forwards, but when the polar plates are stacked in practical use, as the lead plaster is a mud-shaped object, when the lead plaster falls onto the conveying belt, concave-convex plaster can be formed, and when the polar plates are stacked, the lead plaster falls onto the polar plates to form the convex plaster. Due to the structural decision of the plate coating machine, residual paste adhesion can occur on the edge of a polar plate, if the polar plate drops into a battery, the battery can be directly scrapped due to short circuit, and a worker is required to scrape the residual paste by using a manual scraper.

The invention patent with publication number CN 106219204 a discloses a board collecting device, which comprises: a first conveyor belt for continuously conveying the electrode plates; the arrangement of the second conveyor belt, the counting sensor and the piece throwing device enables the polar plates to be neatly and stably stacked and collected, and certain automation capacity is achieved.

The utility model discloses an authorization notice number is CN 202103119U's utility model discloses a battery polar plate that possesses automatic counting function scribbles board line and uses board collecting device installs one set of counting system that can report to the police and take automatic zero clearing function when the setting value additional on scribbling board line board collecting device, and this system can realize accurate count and statistics to send audible alarm after reaching the board quantity of giving birth to of a solidification frame.

The above two patents have achieved certain effects on the degree of automation, but do not improve the phenomena of scratching of the plate, concave-convex paste, residual paste of the plate, etc., and seriously affect the operation of the subsequent processes and the battery performance.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to the not enough that exists among the prior art, provide one kind when piling up comparatively soft, prevent to form the polar plate of unsmooth cream on the polar plate and receive piece device.

A polar plate collecting device comprises a first conveying belt and a second conveying belt, wherein the first conveying belt is used for conveying polar plates coated by a coating machine, the second conveying belt is used for stacking and conveying the polar plates, and the input end of the second conveying belt is connected with the output end of the first conveying belt; the polar plates are connected, connecting strips are arranged on two sides perpendicular to the conveying direction, hanging lugs are arranged on the outer sides of the front portions of the connecting strips, the conveying surface of the second conveying belt is lower than the conveying surface of the first conveying belt, a stacking mechanism for assisting in stacking the polar plates is arranged at the input end of the second conveying belt, the stacking mechanism comprises two receiving strips extending into the upper portion of the second conveying belt from two sides, and the height of the receiving strips is not higher than the conveying surface of the first conveying belt; the receiving strip is divided into an upstream section for receiving the tail part of the connected polar plate and a downstream section for receiving the hanging lugs of the connected polar plate in the polar plate conveying direction, the distance between the upstream sections of the two receiving strips is smaller than the width between the two connecting strips of the connected polar plate, and the distance between the downstream sections of the two receiving strips is larger than the width between the two connecting strips of the connected polar plate and smaller than the width between the two hanging lugs of the connected polar plate.

Wherein, the upstream and the downstream are divided according to the conveying direction of the continuous polar plate, and the continuous polar plate is conveyed from the upstream to the downstream. The spacing between the upstream and downstream sections of the ribbons does not include the width of the ribbons. The width between the two connecting strips of the connected polar plate comprises the width of the connecting strip; the width between the two lugs of the connected polar plate also includes the width of the lug.

Preferably, the length of the downstream section of the bearing strip along the polar plate conveying direction is consistent with the length of the connected polar plate from the rear end of the hanging lug to the tail end of the connected polar plate. When the downstream section of the receiving strip is parallel to the pole plate conveying method, the length of the receiving strip along the pole plate conveying direction is equal to the length of the downstream section; when the downstream section of the receiving strip is inclined at a certain angle with the polar plate conveying method, the length of the downstream section along the polar plate conveying direction is the length of the projection of the downstream section in the polar plate conveying direction. When the hanging lug of the connected polar plate slides out of the bearing strip, the two sides of the tail of the connected polar plate just slide out of the upstream section of the bearing strip, the distance between the two downstream sections of the bearing strip is wider, and the tail of the connected polar plate also falls off at the same time, so that the whole connected polar plate can fall off from the bearing strip at the same time in the front and at the back, and the connected polar plate is favorably and neatly stacked.

More preferably, the two receiving strips are arranged in a splay shape, wherein the upstream ends are close to each other and the downstream ends are far away from each other; the distance between the upstream ends of the two bearing strips is smaller than the width between the two connecting strips of the connected polar plate, and the distance between the downstream ends of the two bearing strips is larger than the width between the two connecting strips of the connected polar plate and smaller than the width between the two hangers of the connected polar plate. The bearing strips are designed to be arranged in a splayed shape, and the upstream section and the downstream section are integrally formed, so that the installation of the bearing strips is convenient.

It is further preferred that the carrier strip is progressively raised from the upstream end to the downstream end. The design can make the continuous polar plate meet certain resistance and will slow down speed when sliding the in-process forward along accepting the strip for the speed that makes continuous polar plate when dropping from accepting the strip forward is slow enough, makes continuous polar plate pile up more level and more smooth.

The stacking mechanism further comprises two elastic supporting pieces extending into the second conveying belt and between the bearing strips from two sides, and the elastic supporting pieces are used for supporting the tail portions of the connected polar plates sliding down from the bearing strips. The elastic supporting sheet is made of a steel sheet with the thickness of 0.4-0.6 mm. The tail part of the connected polar plate falling from the bearing strip falls onto the elastic support sheet, then the elastic support sheet gradually bends and falls along with the continuous stacking of the connected polar plate, so that the buffering effect is achieved, the polar plate is stacked flatly and is not easy to form concave-convex paste.

The output end of the first conveying belt is provided with a sheeting roller, and a gap for the polar plate to pass through is formed between the sheeting roller and the first conveying belt; the polar plate collecting device further comprises a V-shaped scraper which spans the first conveying belt and is used for scraping lead plaster adhered to the surface of the pressing roller, the cross section of the V-shaped scraper is of a V-shaped structure, and a cutting edge attached to the surface of the pressing roller is arranged on one side close to the pressing roller. The pressing roller presses the connected polar plates to enable the lead plaster to be combined with the grid more tightly. However, lead paste may be adhered to the pressing roller, pits may be formed in the connected polar plates when the connected polar plates are continuously rolled, and the V-shaped scraper is used for scraping the lead paste adhered to the surfaces of the pressing roller, so that the surface smoothness of the subsequent connected polar plates is guaranteed.

And a blowing mechanism used for blowing off free lead plaster falling on the polar plate is arranged at the downstream of the stacking mechanism, the blowing mechanism comprises a blowing pipe crossing the second conveying belt, and a blowing seam is arranged on one side of the blowing pipe facing the stacking mechanism. The width of the air blowing seam is 0.2-0.4 mm, and the length of the air blowing seam is larger than the width of the polar plate. The blowing mechanism is used for blowing off lead plaster particles which may fall off the connected polar plate, so that the phenomenon that the lead plaster particles are adhered to the surface of the connected polar plate to cause concave-convex plaster on the surface of the connected polar plate during stacking is avoided. The blowing seam blows air from the downstream to the upstream of the polar plate conveying direction, and the blown lead plaster particles are blown away from one side of the input end of the second conveying belt, so that the downstream condition is not influenced. One end of the air blowing pipe is connected with an air source, and the air source can be an independent high-pressure air bottle and an air compressor or is connected with a high-pressure air system of a factory.

And two groups of scrapers used for scraping residual paste adhered to the front side and the rear side of the polar plate are arranged at the downstream of the blowing mechanism, and the scrapers are driven by the cylinder to move along the direction vertical to the polar plate conveying direction. Each group of scrapers can be one, and the scrapers scrape from one side to the other side of the stacked connected polar plates; or two can be used, respectively scraping from two sides to the middle. The material of scraper can select the PVC material, can not be too hard, is difficult to the scratch polar plate.

The second conveyer belt needs the interval to carry when carrying, and every pile up a pile of even piece polar plate and just carry one section, can set up a count sensor near the output of first conveyer belt and the input of second conveyer belt, then after every count a certain number of even piece polar plates, control the second conveyer belt and carry one section. Or a motor for driving the second conveying belt to run is a stepping motor, so that the purpose that the second conveying belt runs for a section and then pauses for stacking the pole plates to be connected can be achieved.

The utility model discloses a polar plate collecting device is after the continuous polar plate is scribbled the board and is dried through the kiln is done to the table, is carried the low reaches by first conveyer belt a slice, and the continuous polar plate drops to the input of second conveyer belt after throwing out from first conveyer belt, falls on two accepting strips earlier, and the hangers of continuous polar plate front end is taken at the downstream section of accepting the strip this moment, and the afterbody of continuous polar plate is taken at the upstream section of accepting the strip; then because the continuous polar plate has forward inertia, after being caught by the accepting strip, the continuous polar plate can continuously slide forward on the accepting strip, when the hanging lug slides out of the downstream section of the accepting strip, the front end of the continuous polar plate falls off from the accepting strip, when the tail of the continuous polar plate slides out of the upstream section of the accepting strip, the tail of the continuous polar plate falls off from the accepting strip, and the whole continuous polar plate falls on the second conveying belt for stacking after the front end and the tail of the continuous polar plate fall off from the accepting strip.

Because the continuous polar plate is not directly dropped onto the second conveyer belt from the first conveyer belt, but is stacked onto the second conveyer belt after receiving transition of the receiving strip, the impact force of the continuous polar plate dropping is greatly reduced, and the phenomenon that the lead plaster is deformed after the continuous polar plate is dropped, the phenomenon of concave-convex plaster occurs, and the quality of the polar plate is influenced.

Drawings

Fig. 1 is a schematic side view of the polar plate collecting device of the present invention.

Fig. 2 is a partially enlarged view of a in fig. 1.

Fig. 3 is a schematic view of the overlooking structure of the polar plate collecting device of the present invention.

Fig. 4 is a schematic top view of the input end of the second conveyor belt.

Fig. 5 is a side view of the stacking mechanism.

Fig. 6 is a schematic structural view of the V-shaped scraper.

FIG. 7 is a schematic view of the structure of the blowing slit on the blowing tube.

Detailed Description

As shown in fig. 1 to 7, a plate collecting device is used for stacking a continuous plate after being coated by a coating machine and dried by a surface drying kiln, and after stacking, a worker puts the stacked continuous plate on a curing frame to enter a next curing process. In this embodiment, one continuous polar plate 1 includes four single polar plates 11, each single polar plate 11 has a tab 12, two sides of the continuous polar plate 1 have connecting strips 13, and one end of the outer side of the connecting strip 13 is provided with a hanging lug 14. When the connected polar plate 1 is conveyed, the connecting strips 13 are positioned at two sides vertical to the conveying direction, and the hanging lugs 14 are positioned at the front end.

This application polar plate receipts piece device is including being used for carrying through scribbling the first conveyer belt 2 of a slice polar plate 1 behind the trigger board to and be used for piling up and carry the second conveyer belt 3 of a slice polar plate 1, the input of second conveyer belt 3 links up the output of first conveyer belt 2, and the transport face of second conveyer belt 3 is less than the transport face of first conveyer belt 2.

The two sides of the first conveying belt 2 are provided with supports 21, the first conveying belt 2 is installed on the supports 21, the output end of the first conveying belt 2 is provided with a sheeting roller 22, and a gap for the polar plate to pass through is formed between the sheeting roller 22 and the first conveying belt 2. The upstream side of the sheeting roller 22 is provided with a V-shaped scraper 23 which is arranged across the first conveyor belt 2 and used for scraping lead plaster adhered to the surface of the sheeting roller 22, the section of the V-shaped scraper 23 is of a V-shaped structure, and one side close to the sheeting roller 22 is provided with a blade which is attached to the surface of the sheeting roller 22. The V-shaped scraper 23 is fixedly arranged on the bracket 21 at two sides through mounting rods. The pressing roller 22 presses the connected polar plates 1 to enable the lead paste to be combined with the grid more tightly. However, lead paste may be adhered to the sheeting roller 22, which may cause pits to appear on the continuous polar plate 1 when the continuous polar plate 1 is continuously rolled, and the use of the V-shaped scraper 23 to scrape off the lead paste adhered to the surface of the sheeting roller 22 is beneficial to ensuring the surface smoothness of the subsequent continuous polar plate 1.

The input end of the second conveyer belt 3 is provided with a stacking mechanism for stacking auxiliary polar plates, the stacking mechanism comprises two receiving strips 32 extending into the upper part of the second conveyer belt 3 from two sides, and the height of the receiving strips 32 is not higher than the conveying surface of the first conveyer belt 2; the receiving strips 32 are divided into an upstream section for receiving the tail of the continuous polar plate 1 and a downstream section for receiving the lugs 14 of the continuous polar plate 1 in the polar plate conveying direction, the distance between the upstream sections of the two receiving strips 32 is smaller than the width between the two connecting strips 13 of the continuous polar plate 1, and the distance between the downstream sections of the two receiving strips 32 is larger than the width between the two connecting strips 13 of the continuous polar plate 1 and smaller than the width between the two lugs 14 of the continuous polar plate 1.

Wherein, the upstream and the downstream are divided according to the conveying direction of the continuous polar plate 1, and the continuous polar plate 1 is conveyed from the upstream to the downstream. The spacing between the upstream and downstream segments of two carrier strips 32 does not include the width of the carrier strips 32. The width between the two connecting strips 13 of the connected polar plate 1 comprises the width of the connecting strips 13; the width between the two hanging lugs 14 of the connected polar plate 1 also includes the width of the hanging lugs 14.

In a preferred embodiment, the length of the downstream section of the take-up strip 32 in the direction of plate transport corresponds to the length of the continuous plate 1 from the rear end of the lug 14 to the rear end of the continuous plate 1. When the downstream section of the receiving strip 32 is parallel to the pole plate conveying method, the length in the pole plate conveying direction is equal to the length of the downstream section; when the downstream section of the receiving strip 32 is inclined at a certain angle to the pole plate conveying method, the length in the pole plate conveying direction is the length of the downstream section projected in the pole plate conveying direction. When the hanging lug 14 of the connected polar plate 1 slides out of the bearing strip 32, the two sides of the tail of the connected polar plate 1 just slide out of the upstream section of the bearing strip 32, the distance between the downstream sections of the two bearing strips 32 is wider, and the tail of the connected polar plate 1 also falls off at the same time, so that the whole connected polar plate 1 can fall off from the bearing strip 32 at the same time around the whole connected polar plate 1, and the connected polar plate 1 is favorably and neatly stacked.

In a more preferred embodiment, as shown, the two carrier strips 32 are arranged in a "figure-eight" configuration, with upstream ends adjacent to each other and downstream ends remote from each other; the distance between the upstream ends of the two bearing strips 32 is smaller than the width between the two connecting strips 32 of the continuous polar plate 1, and the distance between the downstream ends of the two bearing strips 32 is larger than the width between the two connecting strips 32 of the continuous polar plate 1 and smaller than the width between the two hangers 14 of the continuous polar plate 1. The receiving strips 32 are designed to be arranged in a splayed shape, and the upstream section and the downstream section are integrally formed, so that the mounting of the receiving strips 32 is convenient.

The carrier strip 32 is gradually raised in height from the upstream end to the downstream end. The design can make the continuous polar plate 1 meet certain resistance and will slow down speed in the process of sliding along accepting strip 32 forward for the speed that makes continuous polar plate 1 forward when dropping from accepting strip 32 is slow enough, makes continuous polar plate 1 pile up more level and more smooth.

The second conveyor belt 3 has brackets 31 on both sides, and the second conveyor belt 3 is mounted on the brackets 31. The two receiving bars 32 are respectively fixedly mounted on the bracket 31 at one side by a fixing rod 34.

The stacking mechanism further comprises two elastic supporting pieces 33 extending into the second conveying belt 3 from two sides and between the bearing strips 32, one end of each elastic supporting piece 33 is fixed on the support 31 on one side, and the other end of each elastic supporting piece 33 extends into the position above the second conveying belt 3. The flexible support sheet 33 is used to support the tail of the strip plate 1 which slides down from the receiving strip 32. The elastic support sheet 33 is made of a steel sheet with a thickness of 0.4-0.6 mm. The tail of the connected polar plate 1 falling from the bearing strip 32 falls onto the elastic support sheet 33, then the elastic support sheet 33 gradually bends and falls down along with the continuous stacking of the connected polar plate 1, so that the buffering effect is achieved, the polar plate is stacked flatly and is not easy to form concave-convex paste.

And an air blowing mechanism for blowing off the free lead plaster falling on the pole plates is arranged at the downstream of the stacking mechanism, the air blowing mechanism comprises an air blowing pipe 35 crossing the second conveying belt 3, and an air blowing slit 36 is arranged on one side of the air blowing pipe 35 facing the stacking mechanism. The width of the air blowing seam 36 is 0.2-0.4 mm, and the length is larger than the width of the connected polar plate 1. The blowing mechanism is used for blowing lead plaster particles which may fall off the connected polar plate 1, so that the lead plaster particles are prevented from being adhered to the surface of the connected polar plate 1, and the phenomenon of concave-convex plaster on the surface of the connected polar plate 1 during stacking is avoided. The blowing slit 36 blows air from the downstream to the upstream of the pole plate conveying direction, and the blown lead plaster particles are blown away from the input end side of the second conveying belt 3, so that the downstream condition is not influenced. One end of the gas blowing pipe 35 is connected to a gas source, which may be an independent high-pressure gas cylinder, an air compressor, or a high-pressure gas system of a factory.

The low reaches of this application mechanism of blowing is equipped with two sets of scrapers 37 that are used for striking off the surplus cream of even piece polar plate 1 front and back both sides adhesion, and scrapers 37 are driven by cylinder 38 and are removed along perpendicular polar plate direction of delivery. Each group of scrapers 37 can be one, and scrapes from one side to the other side of the stacked connected polar plates 1; or two can be used, respectively scraping from two sides to the middle. The scraper 37 can be made of PVC material, and is not too hard and not easy to scratch the polar plate. In the illustrated embodiment, as shown in fig. 3, there are two scrapers 37 in each set, and the air cylinder 38 is fixed to the brackets 31 on both sides, and the scrapers 37 are fixed to the top of the piston rod 39 of the air cylinder 38.

The second conveyer belt 3 needs the interval to be carried when carrying, and every pile up a pile of even piece polar plate 1 and just carry one section, can set up a count sensor near the output of first conveyer belt 2 and the input of second conveyer belt 3, then every count a certain number even piece polar plate 1 back, control second conveyer belt 3 and carry one section. Or a motor for driving the second conveying belt 3 to run is a stepping motor, so that the purpose that the second conveying belt 3 runs for a section and then pauses for stacking the polar plates 1 to be connected can be achieved.

The utility model discloses piece collecting device is after even piece polar plate 1 scribbles the board and dry kiln is dried through the table, is carried the low reaches by 2 pieces of first conveyer belt, even piece polar plate 1 is after throwing from first conveyer belt 2, falls to the input of second conveyer belt 3, falls on two accepting strips 32 earlier, and the hangers 14 of even piece polar plate 1 front end are taken at the downstream section of accepting strip 32 this moment, and the afterbody of even piece polar plate 1 is taken at the upstream section of accepting strip 32; then, because the continuous plate 1 has forward inertia, after being received by the receiving strip 32, the continuous plate 1 slides forward on the receiving strip 32, when the hanging lug 14 slides out of the downstream section of the receiving strip 32, the front end of the continuous plate 1 falls off from the receiving strip 32, when the tail of the continuous plate 1 slides out of the upstream section of the receiving strip 32, the tail of the continuous plate 1 falls off from the receiving strip 32 onto the elastic support piece 33, the front end and the tail of the continuous plate 1 both fall off from the receiving strip 32 and then are stacked, and then as the continuous plate 1 is stacked, the elastic support piece 33 bends gradually and falls down onto the second support piece 3. In the stacking process of the connected polar plates 1, the air blowing pipe 35 blows air from the downstream to the upstream direction of the polar plate conveying direction through the air blowing seam 36, so as to blow off lead plaster particles which may fall off from the connected polar plates 1, and the blown-off lead plaster particles are blown away from the input end side of the second conveying belt 3. After the stacking of the connected polar plates 1 is completed, the second conveyer belt 3 conveys the connected polar plates 1 to the downstream, and when the connected polar plates are conveyed to the two groups of scrapers 37, the air cylinder 38 drives the scrapers 37 to scrape off residual paste adhered to the front side and the rear side of the connected polar plates 1 once. And finally, stacking the stacked connected polar plates 1 on a curing frame, and entering the next procedure.

Claims (10)

1. A polar plate collecting device comprises a first conveying belt and a second conveying belt, wherein the first conveying belt is used for conveying polar plates coated by a coating machine, the second conveying belt is used for stacking and conveying the polar plates, and the input end of the second conveying belt is connected with the output end of the first conveying belt; the polar plate is a connected polar plate, connecting strips are arranged on two sides perpendicular to the conveying direction, and hanging lugs are arranged on the outer sides of the front parts of the connecting strips; the receiving strip is divided into an upstream section for receiving the tail part of the connected polar plate and a downstream section for receiving the hanging lugs of the connected polar plate in the polar plate conveying direction, the distance between the upstream sections of the two receiving strips is smaller than the width between the two connecting strips of the connected polar plate, and the distance between the downstream sections of the two receiving strips is larger than the width between the two connecting strips of the connected polar plate and smaller than the width between the two hanging lugs of the connected polar plate.

2. The plate collecting device of claim 1, wherein the length of the downstream section of the receiving strip along the plate conveying direction is consistent with the length of the connected plate from the rear end of the hanging lug to the tail end of the connected plate.

3. The plate collecting device according to claim 2, wherein the two receiving strips are arranged in a splayed arrangement in which the upstream ends are close to each other and the downstream ends are far from each other; the distance between the upstream ends of the two bearing strips is smaller than the width between the two connecting strips of the connected polar plate, and the distance between the downstream ends of the two bearing strips is larger than the width between the two connecting strips of the connected polar plate and smaller than the width between the two hangers of the connected polar plate.

4. The plate collecting device of claim 3, wherein the carrier strip is gradually raised from the upstream end to the downstream end.

5. The plate collector of claim 1, wherein the stacking mechanism further comprises two flexible support tabs extending from either side between the second conveyor and the carrier strip, the flexible support tabs configured to support the tail of a continuous plate slid down the carrier strip.

6. The plate collecting device of claim 5, wherein the elastic supporting plate is made of a steel plate with a thickness of 0.4-0.6 mm.

7. The polar plate collecting device as claimed in claim 1, wherein the output end of the first conveyer belt is provided with a sheeting roller, and a gap for the polar plate to pass through is formed between the sheeting roller and the first conveyer belt; the polar plate collecting device further comprises a V-shaped scraper which spans the first conveying belt and is used for scraping lead plaster adhered to the surface of the pressing roller, the cross section of the V-shaped scraper is of a V-shaped structure, and a cutting edge attached to the surface of the pressing roller is arranged on one side close to the pressing roller.

8. The pole plate collecting device of claim 1, wherein a blowing mechanism for blowing off free lead paste falling on the pole plates is arranged downstream of the stacking mechanism, the blowing mechanism comprises a blowing pipe crossing the second conveying belt, and a blowing slit is arranged on the blowing pipe and faces to one side of the stacking mechanism.

9. The pole plate collecting device of claim 8, wherein the width of the air blowing slit is 0.2-0.4 mm, and the length of the air blowing slit is larger than the width of the pole plate.

10. The pole plate collecting device according to claim 8, wherein two groups of scrapers for scraping off residual paste adhered to the front side and the rear side of the pole plate are arranged at the downstream of the air blowing mechanism, and the scrapers are driven by an air cylinder to move along the direction vertical to the pole plate conveying direction.

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