CN114400385B - Polar plate connecting lamination device and lamination method - Google Patents

Abstract

The invention discloses a polar plate connecting lamination device, which comprises: the clamping type conveying belt group comprises at least two groups of clamping type conveying belts which are arranged side by side at intervals and are synchronous, and the clamping type conveying belts are used for clamping plate thickness sides of a single row of plates in at least two rows of plates in a connecting and stacking mode and are used for continuously conveying the plates; the slitting mechanism comprises a slitting piece, the slitting piece is arranged in the parallel interval of the clamping type conveying belt, and the slitting mechanism is used for slitting the combined slitting surface of the polar plate connecting piece stack, and the combined slitting surface extends along the conveying direction of the clamping type conveying belt. The polar plates are vertically overlapped, the stress is uniform in the slitting and discharging processes of each polar plate, the probability of the liquid substance in the polar plate lead paste seeping to the polar plate surface of the coated paper polar plate is lower, and a surface drying kiln in the polar plate production process can be omitted; the energy consumption is reduced; the water content of the polar plates tends to be reasonably controlled, the water content of the polar plates in the same batch tends to be consistent, and the subsequent additional polar plate humidifying operation is avoided. The invention also discloses a grid coating and slitting process.

Description

Polar plate connecting lamination device and lamination method

Technical Field

The invention relates to the technical field of lead-acid storage battery polar plate production, in particular to a polar plate connecting and laminating device and a polar plate connecting and laminating method.

Background

The production of the accumulator plate mainly comprises: producing grids, filling the grids with lead plaster, cutting, discharging and the like. The product of the lead plaster filled grid comprises the grid, the lead plaster filled on the through holes and the surface of the grid and the coated paperboard covered on the lead plaster coating area.

In order to ensure orderly discharge of the plates, it is generally necessary to provide a plate-coating palletizing device as disclosed in CN213201524U, which comprises a mechanical gripper for gripping the stack of battery plates. Stacking of the coated plates necessarily results in the bottom coated plate being pressed more than the top coated plate, which in turn results in liquid material in the bottom plate lead paste seeping into the coated paper and even between adjacent coated plates. The vacuum adsorption transfer to the plates and the clamping of the plate stack also lead to the problems described above. The improved technical scheme is that a surface drying kiln is arranged before stacking the polar plates, and the surfaces of the coated plates are subjected to primary drying. However, the surface drying treatment is unfavorable for controlling the water loss of the lead plaster in the coated plate, thereby affecting the quality of the grid. In actual production, a humidifying step is required to be additionally arranged on a grid with low water content so as to meet the assembly requirement of a lead-acid storage battery; in addition, the smaller the size of the polar plate, the lower the stability of the coating plate stack, and the difficulty of orderly discharging is increased.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides a polar plate connecting lamination device, wherein lamination is realized by utilizing the position change of polar plate connecting pieces on a feeding conveyer belt and a hanging conveyer belt, equipment such as a lamination manipulator is omitted, and the surface stress of the polar plate connecting pieces is uniform in the lamination process.

In order to achieve the technical effects, the technical scheme of the invention is as follows: a pole plate connecting lamination device comprising:

the feeding conveyor belt is used for conveying the polar plate connecting pieces which are tiled and sequentially arranged along the conveying direction;

The feeding end of the hanging conveyor belt is arranged side by side with the discharging end of the feeding conveyor belt, the working surface of the feeding end is lower than the working surface of the discharging end of the feeding conveyor belt, and the working surface of the hanging conveyor belt is used for bearing and vertically hanging the turnover polar plate connecting piece of the discharging end of the feeding conveyor belt, and is hung with a process connecting strip or a polar lug extending along the width direction of the hanging conveyor belt in the polar plate connecting piece;

and the lamination assembly is used for driving the polar plate connecting piece connected with the hanging conveyor belt to be overlapped with the front and rear plates.

The preferable technical scheme is that the feeding end of at least one suspension conveyer belt is clamped in the parallel interval of the discharging ends of the feeding conveyer belt.

The preferable technical scheme is that the lamination assembly is a clamping type conveying belt and is used for bearing polar plate connecting piece stacks of the hanging conveying belt; the conveying speed of the clamping type conveying belt is smaller than that of the hanging conveying belt.

The preferable technical scheme is that the method further comprises the following steps:

the rolling shearing mechanism is used for rolling shearing and continuously coating plates to obtain polar plate connecting pieces; the feeding conveyer belt is arranged below a discharge hole of the rolling shear mechanism.

The preferable technical scheme is that an alignment adjusting mechanism is arranged on the side of the hanging conveyor belt and/or the feeding conveyor belt, and the alignment adjusting mechanism is used for adjusting polar plate connecting pieces on the hanging conveyor belt and/or the feeding conveyor belt to be aligned along the conveying direction.

The preferred technical scheme is that the alignment adjusting mechanism comprises:

The pushing and blocking piece is arranged at the side of the hanging conveyor belt and/or the feeding conveyor belt and is used for pushing and blocking the plate thickness side face of the polar plate connecting piece;

and the telescopic piece is connected with the pushing and blocking piece and drives the pushing and blocking piece to be close to and far away from the side edge of the feeding conveyor belt and/or the hanging conveyor belt.

The second object of the invention is to provide a method for laminating a grid coating plate, which comprises the following steps:

S05: the plate connecting pieces are horizontally paved and sequentially arranged along the conveying direction, each plate connecting piece comprises at least two plates, and the plates are arranged along the width direction of the feeding conveying belt and are connected through lugs or process connecting strips extending along the width direction;

s07: the polar plate connecting piece of the feeding conveyer belt is turned over for blanking, and the hanging conveyer belt is connected with a process connecting strip or a polar lug extending along the width direction of the hanging conveyer belt in the polar plate connecting piece in a hanging manner; the lamination assembly drives the polar plates connected with the hanging conveyor belt to be overlapped from the front to the back.

The preferable technical scheme is that before S05, the method further comprises the following steps:

s03: and rolling shearing the continuous coating plates by rolling shearing equipment, and sequentially falling the obtained polar plate connecting pieces on a feeding conveyor belt for outputting.

The preferable technical scheme is that before S03, the method further comprises the following steps:

s01: and feeding the continuous grids into a coating device to obtain the continuous coating plate.

The preferable technical scheme is that the method further comprises the following steps: the alignment adjusting mechanism at the side of the feeding conveyor belt and/or the hanging conveyor belt pushes the polar plate connecting piece until the polar plate connecting piece is aligned along the conveying direction of the feeding conveyor belt and/or the hanging conveyor belt.

The invention has the advantages and beneficial effects that:

the polar plate connecting piece lamination device comprises a feeding conveyer belt and a hanging conveyer belt, and polar plate connecting pieces are utilized to turn over and bear between the discharge end of the feeding conveyer belt and the discharge end of the hanging conveyer belt until front and back pieces are overlapped;

Compared with stacking up and down, the stress of each polar plate in the stacked state is even, the probability of liquid substances in the polar plate lead paste seeping out to the polar plate surface of the coated paper is lower, and a surface drying kiln in the polar plate production process can be omitted; the water content in the polar plates tends to be more reasonably controlled while the energy consumption is reduced, the water content in the polar plates in the same batch tends to be consistent, and the subsequent additional polar plate humidifying operation is also avoided;

The arrangement of a lamination manipulator is omitted, and the structure of the grid coating and lamination device is simplified.

Drawings

FIG. 1 is a schematic top view of an embodiment of a plate-and-sheet lamination apparatus;

FIG. 2 is a schematic diagram of a front view of the feed conveyor belt, hanging conveyor belt and lamination assembly of an embodiment;

FIG. 3 is a schematic front view of a feed conveyor belt, a hanging conveyor belt and a lamination assembly in another embodiment;

FIG. 4 is a schematic top view of another embodiment of a plate-and-plate lamination apparatus in use;

In the figure: 1. a feed conveyor belt; 2. hanging a conveying belt; 3. a rolling shear mechanism; 4. an alignment adjustment mechanism; 41. a push block; 42. a telescoping member; 5. a lamination assembly; 51. a supporting conveyer belt; 52. positioning a conveying belt; a. the polar plates are connected; a1, pole lugs; a2, a plate main body.

Detailed Description

The following describes the embodiments of the present invention further with reference to the drawings and examples. The following examples are only for more clearly illustrating the technical aspects of the present invention, and are not intended to limit the scope of the present invention.

Examples

As shown in fig. 1-2, the polar plate connecting lamination device comprises a feeding conveyer belt 1 and a hanging conveyer belt 2, wherein the feeding conveyer belt 1 is used for conveying polar plate connecting plates a which are tiled and are sequentially arranged along the conveying direction; the hanging conveyer belt 2, the feeding end is arranged side by side with the discharging end of the feeding conveyer belt 1, the working surface of the feeding end is lower than the working surface of the discharging end of the feeding conveyer belt 1, the working surface is connected with a process connecting strip or a lug extending along the width direction of the hanging conveyer belt 2 in the polar plate connecting strip a in a hanging manner, the polar plate connecting strip a is used for receiving the overturning polar plate connecting strip a of the discharging end of the feeding conveyer belt 1, and the polar plate connecting strip surface in the hanging state is consistent with the plumb direction; the lamination assembly is used for driving the polar plate connecting piece connected with the hanging conveyor belt in a hanging mode to be overlapped with the front and rear plates. In the figure, the feeding conveyor 1 and the hanging conveyor 2 are aligned in the conveying direction.

The number of the feeding conveyer belts 1 can be one or more than two, and the number of the hanging conveyer belts 2 can be one or more than two, depending on the number of the polar plates in the polar plate connecting piece a. In the figure, the number of the polar plates arranged side by side in the polar plate connecting piece a is two, the polar lugs a1 of the two polar plates extend along the side by side direction and are butted, the single polar plate comprises a rectangular plate main body a2 and the polar lugs a1, and the plate main body a2 and the polar lugs a1 are integrally connected. Correspondingly, the number of the feeding conveyer belts 1 is two, the two feeding conveyer belts 1 respectively support the polar plate bodies in the polar plate connecting piece a, the number of the hanging conveyer belts 2 is one, and the hanging conveyer belts are clamped between the discharging ends of the feeding conveyer belts 1. Preferably, two polar plates in the polar plate connecting piece a hung on the hanging conveyor belt 2 are symmetrically arranged at two ends of the butt joint polar lug a1, so that blanking is ensured to accurately and stably fall onto the hanging conveyor belt 2 in the bearing process, and balance of the polar plate connecting piece a in a hanging state is ensured.

Specifically, in the flat state of the polar plate connecting piece a, the polar lug a1 extending along the side-by-side direction and/or the first side plate thickness side surface of the process connecting strip are predetermined hanging surfaces which are in contact with the working surface of the hanging conveyor belt 2; the gravity center of the polar plate connecting piece a is positioned at the first side of the hanging surface. The plate connecting piece part at the first side of the hanging surface of the plate connecting piece a in a flat state extends out of the discharge end of the feeding conveyer belt, the gravity center is suspended, the plate connecting piece part at the first side of the hanging surface is turned downwards, the connecting piece part at the second side of the hanging surface opposite to the first side is turned upwards, and the front and back piece superposition of the plate connecting piece a in a hanging state is realized by utilizing the carrying and turning actions of the plate connecting piece a on the feeding conveyer belt 1 and the hanging conveyer belt 2.

The number of the unit polar plates in the polar plate connecting piece a can be more than three, the three unit polar plates are connected through the process connecting strip and the butt joint polar lug a1, and the hanging conveyer belt 2 is hung with the process connecting strip, the butt joint polar lug a1 and the opposite polar lug a1 (the polar lugs a1 which extend along the polar plate side by side direction but are not in butt joint). Based on the balance consideration of the polar plate connecting piece a in the hanging state, the structure of the polar plate connecting piece a needs to be matched with the arrangement of the hanging conveying belt 2.

The lamination assembly 5 is a clamping type conveying belt and is used for receiving a polar plate connecting sheet stack (polar plate connecting sheets with front and rear sheets stacked) of the hanging conveying belt 2 and keeping continuous output of the stacked sheets, and the conveying direction of the clamping type conveying belt is consistent with that of the hanging conveying belt; the conveying speed of the gripper conveyor belt is smaller than the conveying speed of the hanging conveyor belt 2. Specifically, when the discharge end polar plate connecting piece a of the hanging conveyor belt 2 is in a lamination state, the clamping conveyor belt is started, and in subsequent production, the conveying speeds of the hanging conveyor belt 2 and the clamping conveyor belt are regulated, so that the discharge end polar plate connecting piece a of the hanging conveyor belt 2 is always kept in a lamination state. In particular, the gripper conveyor belt may grip opposite sides of the plate pack, or top and bottom surfaces, preferably top and bottom surfaces. The clamping type conveyer belt in the figure comprises a bearing conveyer belt 51 and a positioning conveyer belt 52, wherein the front and back plate connecting pieces are pressed on the working surface of the bearing conveyer belt 51, and the working surface of the positioning conveyer belt 52 is pressed on the top surface of the front and back plate connecting pieces. The distance between the top surface and the bottom surface of the polar plate connecting piece a (polar plate connecting piece stack) of the front and the rear plates is consistent, the distance between the top surface and the bottom surface of the non-overlapped state is smaller, and the polar plate connecting piece stack is stably clamped between the clamping surfaces on the basis of fixed spacing between the clamping surfaces of the clamping type conveying belt.

As shown in fig. 4, the lamination device of the polar plate connecting piece a further comprises a rolling shearing mechanism 3 for rolling shearing and continuously coating the plates to obtain the polar plate connecting piece a; the feeding conveyer belt 1 is arranged below a discharge hole of the rolling shear mechanism 3. The rolling shear mechanism 3 is provided with a transverse knife which is axially consistent with the slitting roller, and the rolling shear continuously coats the parting line in the width direction of the plate; or the transverse knife and the longitudinal knife are arranged around the roll surface of the slitting roll, slitting lines in the width direction and the length direction of the continuous coating plate are cut in a rolling manner, and the polar plate connecting piece a which is discharged in sequence is obtained and falls on the working surface of the feeding conveyor belt 1 and is in a flat state, the polar plate arrangement direction of the polar plate connecting piece a is consistent with the bandwidth direction of the feeding conveyor belt 1, and the two directions are identical or slightly have deviation.

As shown in fig. 4, the hanging conveyor belt 2 and the feeding conveyor belt 1 are provided with an alignment regulating mechanism 4 on the side thereof, and the alignment regulating mechanism 4 is used for regulating the polar plate connecting piece a on the hanging conveyor belt 2 and the feeding conveyor belt 1 to be aligned along the conveying direction.

The alignment regulating mechanism 4 as shown in fig. 4 includes: the pushing block 41 and the telescopic piece 42 are air cylinders, and the pushing block 41 is arranged at the side of the hanging conveyor belt 2 and the feeding conveyor belt 1 and is used for pushing and blocking the plate connecting plate a plate thickness side surface of the hanging conveyor belt 2 and the feeding conveyor belt 1 protruding out of the side edge of the working surface; the telescopic piece 42 is connected with a piston rod of a cylinder of the pushing and blocking piece 41, the cylinder body of the cylinder is fixedly arranged at the lateral sides of the hanging conveyor belt 2 and the feeding conveyor belt 1, and the piston rod stretches out and retracts to drive the pushing and blocking piece 41 to be close to and far away from the lateral sides of the feeding conveyor belt 1 and the hanging conveyor belt 2. The feeding conveyer belt 1 and the hanging conveyer belt 2 continuously feed, the air cylinder extends out, the pushing piece 41 moves to the first station, in the process, one or more than two polar plate connecting pieces a are pushed and blocked, the air cylinder retracts, and the pushing piece 41 moves to the second station; and the pole plate connecting piece a is stretched out again and is pushed until the pole plate connecting pieces a on the feeding conveyer belt 1 and the hanging conveyer belt 2 are aligned along the conveying direction. The alignment adjusting mechanism 4 on the side of the feeding conveyer belt 1 is used for overcoming the problem that the tiling orientation of the polar plate connecting pieces a is inconsistent, ensuring that each polar plate connecting piece on the feeding conveyer belt 1 can be stably output to the hanging conveyer belt 2, and the alignment adjusting mechanism 4 on the side of the feeding conveyer belt 1 of the hanging conveyer belt 2 is used for fine adjustment of polar plate connecting piece lamination, so that the follow-up equipment can clamp the side face of the combined plate thickness conveniently. The side surface of the combined plate thickness of the Ji Jiban connecting piece a on the hanging conveyor belt 2 is in a plane shape, the grid of the polar plate is made of lead material, the polar plate has stable rigidity, the factors are favorable for stably clamping the superposed polar plate connecting piece a by adopting a clamping mechanism, and then the next slitting step is carried out. Specifically, the expansion and contraction direction of the expansion and contraction member 42 is consistent with the bandwidth direction of the corresponding feeding conveyer belt 1 and hanging conveyer belt 2; the pushing and blocking pieces 41 are simultaneously arranged on two sides of at least one of the feeding conveyor belt and the hanging conveyor belt, and the pushing and blocking pieces on two sides simultaneously push and block the polar plate connecting pieces to correct deflection of the polar plate connecting pieces. Alternatively, the alignment adjustment mechanism 4 may also be a fixed baffle with a guide surface.

The grid coating and stacking method comprises the following steps:

S05: the feeding conveyor belt 1 conveys plate connecting pieces a which are tiled and sequentially arranged along the conveying direction, wherein the plate connecting pieces a comprise at least two plate plates which are arranged along the bandwidth direction of the feeding conveyor belt 1 and are connected through lugs a1 or process connecting strips extending along the bandwidth direction;

S07: the polar plate connecting piece a of the feeding conveyer belt 1 is turned over for blanking, and the hanging conveyer belt 2 is connected with the butt joint polar lug a1 extending along the width direction of the hanging conveyer belt 2 in the polar plate connecting piece a in a hanging way; the lamination assembly 5 drives the pole plate connection pieces a to the front and back pieces which are hung on the hanging conveyor belt 2 to be overlapped.

Further, the lamination assembly 5 of S07 may optionally include a clamping mechanism for clamping the sides of the combined plate thickness of the lamination, including but not limited to a robot, a clamping conveyor belt, etc., and may also be a stop member disposed in the path of the plate web of the suspension conveyor belt, which moves while blocking the plate web, causing the plate web to overlap front and rear. Optionally, the blocking member is disposed at a discharge end of the hanging conveyor belt and/or disposed at a middle section of the hanging conveyor belt.

As shown in fig. 3, the material blocking member is a movable baffle plate 53, the movable baffle plate 53 is arranged above the hanging conveyor belt (optionally arranged at the side of the hanging conveyor belt), and is connected with the telescopic member, and the telescopic member drives the baffle plate to extend out to drive the movable baffle plate 6 to move into the polar plate connecting piece conveying path of the hanging conveyor belt.

As shown in fig. 4, the tab a1 extending in the width direction is the tab a1 disposed opposite and abutted. Alternatively, the tab a1 extending along the width direction is the tab a1 of the polar plate disposed opposite to each other, or the tab a1 of the polar plate extends along the length direction, and the polar plates are connected by the process connection strip.

The feed conveyor 1 has a conveying speed that is greater than the conveying speed of the hanging conveyor 2. The conveying speed of the hanging conveyor 2 is comprehensively determined according to the size (length, width, thickness) of the polar plate and the speed of the feeding conveyor 1. After the polar plate connecting piece a is overturned, the polar plate part positioned above the hanging surface is attached to or abutted against the previous polar plate connecting piece a, and preferably, the polar plate connecting piece a is vertically hung on the surface of the polar plate.

S03 is also included before S05: the rolling shearing equipment rolling shears the continuous coating plate, and the obtained polar plate connecting pieces a are sequentially dropped on the feeding conveyer belt 1 to be output.

S01 is also included before S03: and feeding the continuous grids into a coating device to obtain the continuous coating plate.

The device also comprises an alignment adjusting mechanism 4 on the sides of the feeding conveyor belt 1 and the hanging conveyor belt 2, which pushes the polar plate connecting piece a until the polar plate connecting piece a is aligned along the conveying direction of the feeding conveyor belt 1 and the hanging conveyor belt 2.

The foregoing is merely a preferred embodiment of the present invention, and it should be noted that it will be apparent to those skilled in the art that several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the scope of the invention.

Claims (9)

1. A pole plate connecting lamination device, comprising:

the feeding conveyor belt is used for conveying the polar plate connecting pieces which are tiled and sequentially arranged along the conveying direction;

The feeding end of the hanging conveyor belt is arranged side by side with the discharging end of the feeding conveyor belt, the working surface of the feeding end is lower than the working surface of the discharging end of the feeding conveyor belt, and the working surface of the hanging conveyor belt is used for bearing and vertically hanging the turnover polar plate connecting piece of the discharging end of the feeding conveyor belt, and is hung with a process connecting strip or a polar lug extending along the width direction of the hanging conveyor belt in the polar plate connecting piece;

the lamination assembly is used for driving the polar plate connecting piece connected with the hanging conveyor belt to be overlapped with the front and rear plates;

The lamination assembly is a clamping type conveying belt and is used for receiving the polar plate connecting sheet stack of the hanging conveying belt; the conveying speed of the clamping type conveying belt is smaller than that of the hanging conveying belt.

2. The plate pack stacking device of claim 1 wherein the feed end of at least one of said hanging conveyor belts is clamped in a side-by-side spacing of the discharge ends of said feed conveyor belts.

3. The plate pack lamination apparatus of claim 1, further comprising:

the rolling shearing mechanism is used for rolling shearing and continuously coating plates to obtain polar plate connecting pieces; the feeding conveyer belt is arranged below a discharge hole of the rolling shear mechanism.

4. The plate connecting lamination device according to claim 1, wherein an alignment adjustment mechanism is provided on a side of the hanging conveyor belt and/or the feeding conveyor belt, and the alignment adjustment mechanism is used for adjusting the plate connecting on the hanging conveyor belt and/or the feeding conveyor belt to be aligned along a conveying direction.

5. The plate pack stacking device of claim 4, wherein said alignment adjustment mechanism comprises:

The pushing and blocking piece is arranged at the side of the hanging conveyor belt and/or the feeding conveyor belt and is used for pushing and blocking the plate thickness side face of the polar plate connecting piece;

and the telescopic piece is connected with the pushing and blocking piece and drives the pushing and blocking piece to be close to and far away from the side edge of the feeding conveyor belt and/or the hanging conveyor belt.

6. A grid coating and stacking method, characterized in that the polar plate connecting and stacking device based on any one of claims 1 to 5 comprises the following steps:

S05: the plate connecting pieces are horizontally paved and sequentially arranged along the conveying direction, each plate connecting piece comprises at least two plates, and the plates are arranged along the width direction of the feeding conveying belt and are connected through lugs or process connecting strips extending along the width direction;

s07: the polar plate connecting piece of the feeding conveyer belt is turned over for blanking, and the hanging conveyer belt is connected with a process connecting strip or a polar lug extending along the width direction of the hanging conveyer belt in the polar plate connecting piece in a hanging manner; the lamination assembly drives the polar plates connected with the hanging conveyor belt to be overlapped from the front to the back.

7. The grid coating stack method of claim 6, further comprising, prior to S05:

s03: and rolling shearing the continuous coating plates by rolling shearing equipment, and sequentially falling the obtained polar plate connecting pieces on a feeding conveyor belt for outputting.

8. The grid coating stack method of claim 7, further comprising, prior to S03:

s01: and feeding the continuous grids into a coating device to obtain the continuous coating plate.

9. The grid coating stack method of claim 6, further comprising: the alignment adjusting mechanism at the side of the feeding conveyor belt and/or the hanging conveyor belt pushes the polar plate connecting piece until the polar plate connecting piece is aligned along the conveying direction of the feeding conveyor belt and/or the hanging conveyor belt.