CN210040276U - Battery cover plate processing device - Google Patents

Abstract

The utility model discloses a battery apron processingequipment belongs to machining technical field. This battery apron processingequipment can install conductive component to the battery apron on, battery apron processingequipment includes: a plurality of assembly stations are arranged on the workbench, and the plurality of assembly stations are configured to sequentially assemble a plurality of parts forming the conductive assembly onto the cover plate; and a riveting press configured to rivet the conductive component and the cover plate; and a welding machine configured to weld and fix the riveted conductive assembly and the cover plate; the plurality of assembling stations, the riveting press and the welding machine are sequentially connected through a conveying assembly. The utility model discloses following beneficial effect has: the assembly station, the riveting press and the welding machine are sequentially connected together through the conveying assembly, so that a complete production line is formed, the labor intensity is low, the production cost is low, and the production efficiency is high.

Description

Battery cover plate processing device

Technical Field

The utility model relates to the technical field of machining, especially, relate to a battery apron processingequipment.

Background

With the popularization of new energy automobiles, environment-friendly electric automobiles become a new trend of energy conservation and emission reduction of automobiles. The power battery is a green battery with the best comprehensive performance in the world at present due to high efficiency, safety and reliability. The application field of the power battery is wider and wider. The power battery consists of three parts: the battery comprises a battery cell, a protection circuit and a shell. The housing is divided into a shell and a cover plate, wherein the conductive component is an important component of the cover plate.

Welding of the conductive members is required on the battery cover plate. The welding of the conductive component comprises three processing processes of assembling, riveting and welding the conductive component. In the conventional welding of the conductive assembly, each processing process is independently assembled and processed and independently operated, so that a corresponding production line needs to be configured for each work flow, and then a product processed on the previous production line is manually transported to the next production line. In the welding process of the traditional conductive assembly, the labor intensity of workers is high, the production cost is high, the production efficiency is low, the assembly precision is not high, and the requirement for welding large-batch conductive assemblies cannot be met. Meanwhile, in the actual processing process, the distance between each processing production line is far, and the processing production lines are transported simply by manpower, so that time and labor are wasted, and the production efficiency is greatly influenced.

In view of the above, it is desirable to design a battery cover plate processing apparatus to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a battery apron processingequipment can realize the integration operation, and it is little to have intensity of labour, and manufacturing cost is lower, and the characteristics that the equipment precision is high.

To achieve the purpose, the utility model adopts the following technical proposal:

a battery cover plate processing apparatus capable of mounting a conductive member to a battery cover plate, the battery cover plate processing apparatus comprising:

a plurality of assembly stations are arranged on the workbench, and the plurality of assembly stations are configured to sequentially assemble a plurality of parts forming the conductive assembly onto the cover plate; and

a riveting press configured to rivet the conductive component and the cover plate; and

a welder configured to weld the riveted conductive assembly and the cover plate;

the plurality of assembling stations, the riveting press and the welding machine are sequentially connected through a conveying assembly.

Preferably, the transfer assembly comprises:

a first conveyor configured to convey the cover plate to the plurality of assembly stations; and

the pushing assembly is configured to sequentially convey the cover plate to the riveting machine and the welding machine from the first conveying belt.

Preferably, the first conveyor belt is connected with the pushing assembly to form a closed loop.

Preferably, the pushing assembly comprises a feeding pushing assembly and an discharging pushing assembly, the feeding pushing assembly is configured to move the cover plate out of the first conveyor belt to the riveting machine, and the discharging pushing assembly is configured to move the cover plate out of the riveting machine to the welding machine for welding.

Preferably, the feeding and pushing assembly comprises a guide rail, a sliding block and a third air rod, wherein the sliding block is arranged on the guide rail, the third air rod is arranged on the sliding block, and the third air rod is configured to drive the sliding block to move on the guide rail along the horizontal direction.

Preferably, the pushing assembly further comprises an adjusting assembly configured to adjust the position and angle of the cover plate.

Preferably, a plurality of trays are also included, the trays being capable of carrying and positioning the cover plates.

Preferably, the cover plate is provided with a first through hole and a second through hole, and the first through hole and the second through hole are configured to allow the positive electrode block and the negative electrode block in the conductive assembly to be leaked to the outside.

Preferably, a first manipulator and a second manipulator are further arranged on the workbench, the first manipulator is configured to move away the positioning plate on the tray after welding, and the second manipulator is configured to grab the cover plate for blanking.

Preferably, a stacking area is further arranged on the workbench and is configured to place a plurality of parts for assembling the conductive assembly.

The utility model has the advantages that: the multiple assembly stations, the riveting press and the welding machine are sequentially connected together through the conveying assembly to form a complete production line, each processing device is not required to be configured with a corresponding production line, and then the conductive assembly processed on the previous production line is manually conveyed to the next production line. The integrated operation of the processing of the conductive assembly is realized, the labor intensity is low, the production cost is low, the operation is orderly, the production efficiency is high, meanwhile, the processing is carried out on a production line, the welding precision between the conductive assembly and the cover plate is high, and the requirement of welding the conductive assemblies in batches is met.

The present disclosure introduces a series of concepts in a simplified form that are further detailed in the detailed description section. The summary of the invention is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

Drawings

Fig. 1 is a schematic structural diagram of a battery cover plate processing device provided by the present invention;

fig. 2 is a schematic structural diagram of a battery cover plate processing device provided by the present invention;

fig. 3 is an exploded view of the conductive assembly provided by the present invention;

fig. 4 is a schematic structural diagram of the assembled conductive component provided by the present invention;

fig. 5 is an exploded view of the tray and the positioning plate provided by the present invention;

FIG. 6 is an enlarged partial schematic view at A in FIG. 2;

fig. 7 is a schematic structural diagram of a feeding pushing assembly provided by the present invention.

Description of reference numerals:

in the figure:

1-a second manipulator; 2-a workbench; 3-a first station; 4-a second station; 5-a third station; 6-a fourth station; 7-riveting machine; 8-welding machine; 9-a first conveyor belt; 10-a push component; 11-a palletizing zone; 12-a first manipulator; 13-a second conveyor belt; 14-a cover plate; 15-a third conveyor belt; 16-positive pole column; 17-a negative pole post; 18-lower plastic cement; 19-coating plastic; 20-a conductive block; 21-positive pole block; 22-a negative pole block; 23-a tray; 24-a positioning plate; 25-a first via; 26-a second via; 27-a feed pusher assembly; 28-an adjustment assembly; 29-an adjusting rod; 30-a slide rail; 31-a first gas lever; 32-a guide rail; 33-a slide block; 34-a third air rod; 35-clip groove.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

Any feature disclosed in this specification may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features. Like reference numerals refer to like elements throughout the specification.

Fig. 1 is the utility model provides a battery cover plate processingequipment's structure schematic diagram one, fig. 2 is the utility model provides a battery cover plate processingequipment's structure schematic diagram two, fig. 3 is the utility model provides a conductive component's decomposition schematic diagram, fig. 4 is the utility model provides a conductive component structure schematic diagram after assembling, fig. 5 is the utility model provides a tray and the decomposition schematic diagram of locating plate, fig. 6 is the local enlarged schematic diagram of A department in fig. 2, fig. 7 is the utility model provides a feeding propelling movement subassembly's structure schematic diagram.

With the popularization of new energy automobiles, environment-friendly electric automobiles become a new trend of energy conservation and emission reduction of automobiles. The power battery is a green battery with the best comprehensive performance in the world at present due to high efficiency, safety and reliability. The application field of the power battery is wider and wider. The power battery consists of three parts: the battery comprises a battery cell, a protection circuit and a shell. The housing is divided into a shell and a cover plate, wherein the conductive component is an important component of the cover plate.

Welding of the conductive members is required on the battery cover plate. The welding of the conductive component comprises three processing processes of assembling, riveting and welding the conductive component. In the conventional welding of the conductive assembly, each processing process is independently assembled and processed and independently operated, so that a corresponding production line needs to be configured for each work flow, and then a product processed on the previous production line is manually transported to the next production line. In the welding process of the traditional conductive assembly, the labor intensity of workers is high, the production cost is high, the production efficiency is low, the assembly precision is not high, and the requirement for welding large-batch conductive assemblies cannot be met. Meanwhile, in the actual processing process, the distance between each processing production line is far, and the processing production lines are transported simply by manpower, so that time and labor are wasted, and the production efficiency is greatly influenced.

In order to solve the above problem, the present embodiment provides a battery cover plate processing apparatus. As shown in fig. 1-2, the battery cover plate processing device includes a worktable 2, a riveting press 7 and a welding machine 8. The table 2 is provided with a plurality of assembling stations configured to sequentially assemble a plurality of parts constituting the conductive member to the cover plate 14. The plurality of assembling stations, the riveting machine 7 and the welding machine 8 are connected in sequence through the conveying assembly. The conveying assembly comprises a first conveying belt 9 and a pushing assembly 10, wherein the first conveying belt 9 is connected with the pushing assembly 10 to form a closed ring shape. Wherein the first conveyor belt 9 is configured to convey the cover plate 14 to a plurality of assembly stations, and the pushing assembly 10 is configured to convey the cover plate 14 from the first conveyor belt 9 to the riveting machine 7 and the welding machine 8 in sequence.

The plurality of assembling stations, the riveting machine 7 and the welding machine 8 are sequentially connected together through the conveying assembly to form a complete production line, each processing device is not required to be configured with a corresponding production line, and then the conductive assembly processed on the previous production line is manually conveyed to the next production line. The integrated operation of the processing of the conductive assembly is realized, the labor intensity is low, the production cost is low, the operation is orderly, the production efficiency is high, meanwhile, the processing is carried out on a production line, the welding precision between the conductive assembly and the cover plate 14 is high, and the requirement of welding large-batch conductive assemblies is met.

Specifically, the plurality of assembly stations includes a first station 3, a second station 4, a third station 5, and a fourth station 6. The first station 3, the second station 4, the third station 5, and the fourth station 6 are configured to sequentially assemble a plurality of parts constituting a conductive member onto the cover plate 14. A riveting press 7 is provided on the table 2, the riveting press 7 being configured to rivet the conductive component and the cover plate 14. A welder 8 is disposed on the table 2, the welder 8 being configured to weld the riveted conductive assembly to the cover plate 14.

Further, still be provided with pile up neatly district 11 on the workstation 2, place conductive component in pile up neatly district 11 to make and be convenient for to take and put save time in the assembly process. As shown in fig. 3, the conductive assembly includes a positive post 16, a negative post 17, a lower plastic 18, an upper plastic 19, a conductive block 20, a positive block 21, and a negative block 22. In this embodiment, the first conveyor belt 9 and the pushing assembly 10 form a closed loop, a plurality of trays 23 are arranged on the loop, the trays 23 are always in a circular motion on the loop, and the moving direction of the trays 23 is shown as the arrow direction in fig. 1. Each tray 23 can bear the cover plate 14 and limit the position of the cover plate 14, and the plurality of trays 23 can shorten the working beat of the battery cover plate processing device, so that each station can be continuously processed, and the processing efficiency is improved.

Specifically, a second conveyor belt 13 is further provided on the table 2, and the second conveyor belt 13 is configured to convey the cover sheet 14 to which the conductive component is not welded from the previous processing device to the table 2 for processing, and then to place the cover sheet 14 to which the conductive component is welded on the second conveyor belt 13 and convey the cover sheet to the next processing device for processing by the second conveyor belt 13. The cover plates 14 are no longer required to be transported to each production line by manual transportation, so that the labor intensity is low, the production cost is low, the operation is orderly, and the production efficiency is high.

The positive electrode post 16 and the negative electrode post 17 are assembled at the first station 3 and then placed on the tray 23, and the tray 23 is moved to the second station 4. At the second station 4, the lower plastic 18 is fitted to the positive electrode post 16 and the negative electrode post 17 in the tray 23, then the cover plate 14 transferred from the previous processing apparatus is manually removed from the second conveyor belt 13, the cover plate 14 is fitted to the lower plastic 18 in the tray 23, and the tray 23 is moved to the third station 5. At the third station 5, the upper plastic 19 and the conductive bumps 20 are assembled to the cover plate 14 in the tray 23, and the tray 23 is moved to the fourth station 6. At a fourth station 6, a positive block 21 is assembled to the conductive block 20 and a negative block 22 is assembled to the upper plastic 19 in a tray 23. The assembled conductive assembly is shown in fig. 4. The plurality of trays 23 circularly move among the first station 3, the second station 4, the third station 5 and the fourth station 6, so that the waiting time of the trays 23 in the process of assembling the conductive components can be reduced, and the assembly efficiency of the conductive components is higher.

Specifically, as shown in fig. 5, a positioning plate 24 is further disposed on the workbench 2, the positioning plate 24 is disposed in the stacking area 11, and the positioning plate 24 is placed in the stacking area 11, so that the assembling process is convenient to take and place, and time is saved. After the conductive assembly is assembled to the cover plate 14, the positioning plate 24 is manually placed on the upper side of the cover plate 14 at the fourth station 6, and the edge of the positioning plate 24 is overlapped with the edge of the cover plate 14. The positioning plate 24 is provided with a first through hole 25 and a second through hole 26, and the first through hole 25 and the second through hole 26 are configured to leak the positive electrode block 21 and the negative electrode block 22 to the outside. Through set up first through-hole 25 and second through-hole 26 on locating plate 24, can leak positive pole piece 21 and negative pole piece 22 to outside, cover other positions on apron 14 simultaneously, make when welding positive pole piece 21 and negative pole piece 22, other positions on the apron 14 are not influenced, guarantee the structural integrity of apron 14.

The first through hole 25 is provided mainly for not shielding the positive electrode block 21, and the shape and size of the first through hole 25 may be the same as or different from those of the positive electrode block 21. Preferably, in the present embodiment, the shape of the first through hole 25 is the same as that of the positive electrode block 21, but the size of the first through hole 25 is different from that of the positive electrode block 21, and the first through hole 25 is larger than the positive electrode block 21. Set up the size of first through-hole 25 for being greater than the size of positive pole piece 21, can provide sufficient welding space when welding positive pole piece 21, make welding effect better. In other embodiments, the first through hole 25 may also be made the same size as the positive electrode block 21. The second through hole 26 is provided mainly for the purpose of not shielding the negative electrode block 22, and the shape and size of the second through hole 26 may be the same as the negative electrode block 22 or may be different from the negative electrode block 22. Preferably, in the present embodiment, the shape of the second through hole 26 is the same as that of the negative electrode block 22, but the size of the second through hole 26 is different from that of the negative electrode block 22, and the second through hole 26 is larger than the negative electrode block 22. The size of the second through hole 26 is set to be larger than that of the negative pole block 22, so that when the negative pole block 22 is welded, enough welding space can be provided, and the welding effect is better. In other embodiments, the second through-hole 26 may also be sized the same as the negative block 22.

Specifically, the pushing assembly 10 includes a feed pushing assembly 27, an adjustment assembly 28, and an exit pushing assembly. The adjusting assembly 28 is configured to adjust the position and angle of the cover plate 14 equipped with the conductive assembly, the feeding pushing assembly 27 is configured to move the cover plate 14 out of the first conveyor belt 9 to the riveting press 7, and the discharging pushing assembly is configured to move the cover plate 14 out of the riveting press 7 to the welding machine 8 for welding.

Further, firstly, the feeding pushing assembly 27 pushes the cover plate 14 to the adjusting assembly 28, and the position and the angle of the cover plate 14 are adjusted through the adjusting assembly 28, so that the riveting effect of the riveting press 7 is better when the conductive assembly and the cover plate 14 are riveted and fixed through the appropriate position and angle.

Specifically, as shown in fig. 6, the adjustment assembly 28 includes an adjustment rod 29, a slide rail 30, and a first air rod 31, the slide rail 30 being disposed on the bottom of the adjustment rod 29, and the first air rod 31 being disposed on the adjustment rod 29. When the cover plate 14 inclines during the process of entering the riveting press 7, the adjusting rod 29 slides towards the cover plate 14 along the slide rail 30 under the pushing of the first air rod 31, so that the adjusting rod 29 abuts against the side surface of the cover plate 14, and the position and the angle of the cover plate 14 are adjusted, so that the cover plate 14 obtains a better position and direction, and the riveting is conveniently carried out when entering the riveting press 7.

As shown in fig. 7, the feeding pusher assembly 27 includes a guide rail 32, a slider 33, a second air bar, and a third air bar 34. The slide block 33 is disposed on the guide rail 32, and a second air lever and a third air lever 34 are both disposed on the slide block 33, the second air lever being configured to drive the slide block 33 to ascend and descend in the vertical direction, and the third air lever 34 being configured to drive the slide block 33 to move on the guide rail 32 in the horizontal direction. Be provided with joint groove 35 on the slider 33, tray 23 bottom is provided with the joint boss with joint groove 35 assorted. When the cover plate 14 is conveyed to the feeding pushing assembly 27, the sliding block 33 is driven by the third air rod 34 to move to the bottom of the cover plate 14 along the guide rail 32, the top end of the sliding block 33 is in contact with the bottom of the tray 23, and the sliding block 33 is driven by the second air rod to ascend in the vertical direction so that the clamping groove 35 in the sliding block 33 is clamped with the clamping boss at the bottom of the tray 23. Under the driving of the third air rod 34, the sliding block 33 carries the tray 23 to move to the riveting machine 7 along the direction of the guide rail 32, and the conductive component and the cover plate 14 are riveted and fixed. The discharging pushing assembly has the same structure as the feeding pushing assembly 27, and further description thereof is omitted. The cover plate 14 can be moved out of the riveting machine 7 to the welding machine 8 for welding through the discharging and pushing assembly, and the conductive assembly and the cover plate 14 are welded and fixed through the welding machine 8. Preferably, in this embodiment, the welder 8 is a laser welder. The laser welding machine has the advantages of small width of a welding line, small heat affected zone, high welding speed, smooth and attractive welding line and no need of treatment or simple treatment after welding. In other embodiments, the welder 8 may also be a multi-function welder or other welder.

Further, a third conveyor 15, a first manipulator 12 and a second manipulator 1 are arranged on the workbench 2, and the welded cover plate 14 is pushed to the first manipulator 12 by the pushing assembly 10. The positioning plate 24 above the cover plate 14 is taken down by the first manipulator 12, then the positioning plate 24 is placed on the third conveyor belt 15, and the positioning plate 24 is conveyed to the stacking area 11 by the third conveyor belt 15 to be placed, so that the next use is facilitated. The cover plate 14 with the positioning plate 24 removed is pushed to the second robot 1 under the action of the pushing assembly 10, and the second robot 1 is configured to remove the cover plate 14, and then put the cover plate on the second conveyor 13 to be conveyed to the next processing equipment by the second conveyor 13 for processing. It is no longer necessary to manually transport the cover plate 14 with the conductive assembly welded thereto to the next processing facility. The labor intensity is reduced, the production cost is reduced, and the production efficiency is improved. While the tray 23 continues to circulate on the loop formed by the first conveyor belt 9 and the pusher assembly 10 for the next assembly of conductive assemblies.

In order to make the technical problem solved by the present invention, the technical solution adopted by the present invention and the technical effect achieved by the present invention clearer, the technical solution of the present invention will be further explained by combining the drawings and by means of the specific implementation manner.

The above description is only for the preferred embodiment of the present invention, and for those skilled in the art, there are variations on the detailed description and the application scope according to the idea of the present invention, and the content of the description should not be construed as a limitation to the present invention.

Claims (10)

1. A battery cover plate processing device capable of mounting a conductive member to a battery cover plate, comprising:

a workbench (2), wherein a plurality of assembling stations are arranged on the workbench (2), and are configured to sequentially assemble a plurality of parts forming the conductive assembly onto a cover plate (14); and

a staking machine (7), the staking machine (7) configured to stake the conductive component and the cover plate (14); and

a welder (8), the welder (8) being configured to weld the riveted conductive assembly and the cover plate (14) together;

the assembling stations, the riveting machine (7) and the welding machine (8) are sequentially connected through a conveying assembly.

2. The battery cover plate processing apparatus as set forth in claim 1, wherein the transfer assembly comprises:

a first conveyor belt (9), said first conveyor belt (9) being configured to convey said cover plates (14) to a plurality of said assembly stations; and

a pushing assembly (10), wherein the pushing assembly (10) is configured to sequentially convey the cover plate (14) from the first conveyor belt (9) to the riveting press (7) and the welding machine (8).

3. The battery cover plate processing apparatus according to claim 2, wherein the first conveyor belt (9) is connected to the push assembly (10) to form a closed loop shape.

4. The battery cover plate processing device according to claim 2, wherein the pushing assembly (10) comprises a feeding pushing assembly (27) and an discharging pushing assembly, the feeding pushing assembly (27) is configured to move the cover plate (14) out of the first conveyor belt (9) to the riveting press (7), and the discharging pushing assembly is configured to move the cover plate (14) out of the riveting press (7) to the welding machine (8) for welding.

5. The battery cover plate processing device according to claim 4, wherein the feeding and pushing assembly (27) comprises a guide rail (32), a slider (33) and a third air rod (34), the slider (33) is arranged on the guide rail (32), the third air rod (34) is arranged on the slider (33), and the third air rod (34) is configured to drive the slider (33) to move on the guide rail (32) along a horizontal direction.

6. The battery cover plate processing device according to claim 2, wherein the pushing assembly (10) further comprises an adjusting assembly (28), and the adjusting assembly (28) is configured to adjust the position and the angle of the cover plate (14).

7. The battery cover plate processing device according to claim 1, further comprising a plurality of trays (23), wherein the trays (23) are capable of carrying and positioning the cover plate (14).

8. The battery cover plate processing apparatus according to claim 7, further comprising a positioning plate (24), wherein the positioning plate (24) is disposed on an upper side of the tray (23) before the conductive member is riveted with the cover plate (14), and a first through hole (25) and a second through hole (26) are provided on the positioning plate (24), and the first through hole (25) and the second through hole (26) are configured to leak the positive electrode block (21) and the negative electrode block (22) in the conductive member to the outside.

9. The battery cover plate processing device according to claim 8, wherein a first manipulator (12) and a second manipulator (1) are further arranged on the workbench (2), the first manipulator (12) is configured to remove the positioning plate (24) on the tray (23) after welding, and the second manipulator (1) is configured to grab the cover plate (14) for blanking.

10. The battery cover plate processing device according to claim 1, wherein a palletizing area (11) is further provided on the workbench (2), the palletizing area (11) being configured to place a plurality of parts for assembling the conductive assembly.

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