CN106876650B - Electric core tab leveling, detecting and cutting system - Google Patents

Abstract

The invention provides a system for leveling, detecting and cutting a lug of a battery cell, which is used for leveling, detecting and cutting the lug of the battery cell and comprises the following components: the conveying line conveys the battery cell through the jig; the leveling device comprises a first leveling module and a second leveling module which are sequentially arranged on one side of the conveying line, and the first leveling module and the second leveling module respectively level two electrode lugs of the battery cell one by one; the detection device is arranged on one side of the conveying line and is positioned at the downstream of the leveling device, and is used for electrically detecting the lug of the battery cell; and the cutting device is arranged on one side of the conveying line and is positioned at the downstream of the detection device, and is used for cutting the electrode lug of the battery cell. According to the invention, an automatic leveling device, a detection device and a cutting device are adopted to cooperate with the conveying line for operation, so that the leveling, detection and cutting of the battery core lug are all automated, and the flow process is realized.

Description

Electric core tab leveling, detecting and cutting system

Technical Field

The invention relates to the field of battery assembly production, in particular to a system for leveling, detecting and cutting a battery core lug.

Background

At present, the battery needs to level and cut the pole lug of a single electric core in the assembling process, and the electric parameters of the pole lug also need to be detected. The existing tab leveling and cutting are operated at independent stations, and are carried out by a single machine, so that the rhythm of battery assembly production is seriously damaged, and the working efficiency of battery assembly is reduced. Moreover, in the process of leveling the electrode lugs of the battery core, automatic operation is difficult to realize, manual participation is needed, the efficiency is reduced, the accuracy is also reduced, and the labor intensity is improved. Moreover, the cutting of the battery core tab cannot be automated at present, manual operation is also needed, the cutting length cannot reach high accuracy, and the efficiency is very low. Finally, the electrical detection of the battery core tab, especially the detection of the open-circuit voltage, the internal resistance and the like, can only be operated by a single machine, and is difficult to realize automatic detection, so that the efficiency of battery assembly production is severely restricted, thereby objectively improving the production cost and reducing the market competitiveness of the product.

Therefore, how to improve the automation level of electric core utmost point ear flattening, detection and cutting to improve battery assembly production efficiency, reduce cost, be the problem that the industry urgently needed to solve.

Disclosure of Invention

A primary object of the present invention is to overcome at least one of the above-mentioned drawbacks of the prior art and to provide a cell tab leveling, detecting and cutting system with high automation level and very high production efficiency.

In order to achieve the purpose, the invention adopts the following technical scheme:

the utility model provides an electric core utmost point ear flattening, detection and cutting system for carry out flattening, detection and cutting to the utmost point ear of electric core, include:

the conveying line conveys the battery cell through a jig;

the leveling device comprises a first leveling module and a second leveling module which are sequentially arranged on one side of the conveying line, and the first leveling module and the second leveling module respectively level two pole lugs of the battery cell one by one;

the detection device is arranged on one side of the conveying line, is positioned at the downstream of the leveling device and is used for electrically detecting the lug of the battery cell;

and the cutting device is arranged on one side of the conveying line and is positioned at the downstream of the detection device, and is used for cutting the electrode lug of the battery cell.

According to an embodiment of the present invention, the two leveling modules are slidably mounted in parallel on a base, and each leveling module includes:

the rack body is fixedly arranged;

the bearing table is arranged on the frame body in a position-adjustable manner, and the battery cell is borne on the bearing surface of the bearing table;

the pressure head is arranged corresponding to the bearing table;

and the driving mechanism is in transmission connection with the pressure head and drives the pressure head to move in the vertical direction of the frame body.

According to an embodiment of the present invention, the bearing table includes an upper bearing table, a lower bearing table and a middle bearing table, the middle bearing table is disposed between the upper bearing table and the lower bearing table and can be withdrawn, and the upper bearing table can move up and down relative to the lower bearing table after the middle bearing table is withdrawn.

According to an embodiment of the invention, the intermediate bearing table is in transmission connection with a traverse cylinder, and the traverse cylinder can drive the intermediate bearing table to move horizontally.

According to an embodiment of the present invention, the lower carrier table is connected to a moving-out mechanism in a transmission manner, the moving-out mechanism can drive the lower carrier table to move out, the moving-out mechanism includes a moving-out nut, a moving-out screw and a motor, the motor is connected to the moving-out screw in a transmission manner, the moving-out screw is connected to the moving-out nut in a matching manner, and the moving-out nut is installed on the lower carrier table.

According to an embodiment of the present invention, the detection device includes:

the base is fixedly arranged;

a guide post mounted on the base;

a first bracket and a second bracket, both movably mounted on the guide post;

detect the platform and detect the structure, it installs to detect the platform on the first support, it installs to detect the structure on the second support, and correspond detect the platform setting.

According to an embodiment of the invention, the inspection station is mounted on an adjustment plate adjustably mounted on the first support by way of the elongated aperture.

According to an embodiment of the present invention, the second bracket is located above the first bracket, and a lifting mechanism is connected to the second bracket so that the second bracket can move up and down along the guide post.

According to an embodiment of the present invention, the cutting device includes:

the rack body is provided with a movable guide rail;

the mounting plate is slidably mounted on the moving guide rail;

the first cutter is slidably mounted on the mounting plate;

the second cutter is slidably mounted on the mounting plate and is arranged corresponding to the first cutter;

the driving mechanism is in transmission connection with the mounting plate and drives the mounting plate to move in the vertical direction of the frame body;

the first lifting mechanism is in transmission connection with the first cutter and drives the first cutter to move in the vertical direction of the mounting plate;

and the second lifting mechanism is in transmission connection with the second cutter and drives the second cutter to move in the vertical direction of the mounting plate.

According to an embodiment of the present invention, the cutting device includes:

the rack body is provided with a movable guide rail;

the first cutter is slidably mounted on the movable guide rail;

the second cutter is fixedly arranged on the frame body and is arranged corresponding to the first cutter;

and the driving mechanism is in transmission connection with the first cutter and drives the first cutter to move in the vertical direction of the frame body.

According to the technical scheme, the battery core tab leveling, detecting and cutting system has the advantages and positive effects that:

according to the invention, the automatic leveling device, the automatic detection device and the automatic cutting device are adopted to be matched with the conveying line for operation, so that the leveling, the detection and the cutting of the battery core lug are all automated, the flow process is realized, the efficiency of battery assembly production is greatly improved, the production cost is objectively reduced, the competitiveness of a product is improved, and the market value is extremely high.

Drawings

Various objects, features and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the invention, when considered in conjunction with the accompanying drawings. The drawings are merely exemplary of the invention and are not necessarily drawn to scale. In the drawings, like reference characters designate the same or similar parts throughout the different views. Wherein:

fig. 1 is a schematic structural diagram of a cell tab flattening, inspecting and trimming system of the present invention shown in an exemplary embodiment.

Fig. 2 is a schematic structural diagram of a leveling device in the cell tab leveling, detecting and cutting system according to the present invention in an exemplary embodiment.

Fig. 3 is an enlarged schematic view of the shielding plate of fig. 2 with a portion removed.

Fig. 4 is a schematic structural diagram of a detection device in the cell tab flattening, detecting and cutting system according to the present invention in an exemplary embodiment.

Fig. 5 is a schematic structural diagram of a cutting device in the cell tab flattening, detecting and cutting system according to the present invention in an exemplary embodiment.

Fig. 6 is a schematic diagram of an elastic capping structure in the cell tab flattening, inspecting and trimming system of the present invention, shown in an exemplary embodiment.

Fig. 7 is a schematic structural diagram of another cutting device in the cell tab flattening, detecting and cutting system according to the present invention in an exemplary embodiment.

Wherein the reference numerals are as follows:

1. a leveling device; 101. a first leveling module; 102. a second leveling module; 11. a frame body; 12. a bearing table; 121. an upper bearing table; 122. a middle bearing table; 123. a lower bearing table; 124. a transverse moving cylinder; 125 regulating the air cylinder; 13. a pressure head; 14. a drive mechanism; 141. a gas-liquid pressure cylinder; 15. a removal mechanism; 151. removing the nut; 152. moving out the screw; 153. a motor; 2. a detection device; 21. a base; 22. a guide post; 23. a first bracket; 24. a second bracket; 25. a detection table; 251. an adjusting plate; 252. a support cylinder; 253. a piston; 26. detecting the structure; 27. a lifting mechanism; 271. a lifting cylinder; 272. a connecting plate; 28 adjusting the structure; 29. a driving cylinder; 3. a cutting device; 30. a sliding base; 301. a fixed seat; 302. adjusting the guide rail; 303. a slider; 304. a drive member; 305. a limiting plate; 31. a frame body; 311. a moving guide rail; 32. mounting a plate; 33. a first cutter; 331 an elastic coping structure; 3311. a pressing head is pressed; 3312. a guide plate; 3313. a guide post; 3314. a spring; 34. a second cutter; 35. a drive mechanism; 351. a cylinder body; 352. a piston; 36. a first lifting mechanism; 361. a first lifting cylinder; 37. a second lifting mechanism; 371. a second lifting cylinder; 372. a side plate; 38. a first connecting plate; 39. a second connecting plate; 4. a conveying line; 5. a cutting device; 50. a sliding base; 501. a fixed seat; 502. adjusting the guide rail; 503. a slider; 504. a drive member; 51. a frame body; 511. a moving guide rail; 52. a first cutter; 521. mounting a plate; 522. an elastic coping structure; 53. a second cutter; 54. a drive mechanism; 541. a cylinder body; 542. a piston; 55. a guide seat; 56. a guide rod; 57. a support frame.

Detailed Description

Example embodiments will now be described more fully with reference to the accompanying drawings. Example embodiments may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of example embodiments to those skilled in the art. The same reference numerals in the drawings denote the same or similar structures, and thus their detailed description will be omitted.

In the following description of various examples of the invention, reference is made to the accompanying drawings, which form a part hereof, and in which are shown by way of illustration various example structures, systems, and steps in which aspects of the invention may be practiced. It is to be understood that other specific arrangements of parts, structures, example devices, systems, and steps may be utilized and structural and functional modifications may be made without departing from the scope of the present invention. Moreover, although the terms "top," "bottom," "front," "back," "side," and the like may be used in this specification to describe various example features and elements of the invention, these terms are used herein for convenience only, e.g., in accordance with the orientation of the examples described in the figures. Nothing in this specification should be construed as requiring a specific three dimensional orientation of structures in order to fall within the scope of the invention.

The system for leveling, detecting and cutting the battery cell lug is used for automatically leveling, detecting and cutting the lug of the battery cell so as to improve the working efficiency and form flow operation, thereby forming an automatic production line.

Fig. 1 is a schematic structural diagram of a cell tab flattening, inspecting and trimming system of the present invention shown in an exemplary embodiment. As shown in fig. 1, the cell tab leveling, detecting and cutting system of this embodiment includes a conveying line 4, a leveling device 1, a detecting device 2 and a cutting device 3. The conveying line 4 conveys the battery core through the jig, and the conveying direction of the battery core is shown by an arrow R in the figure. The form of transfer chain 4 is not limited as long as can reach automatic water flow and carry can to make electric core loop through leveling device 1, detection device 2 and cutting device 3.

In this embodiment, the flattening apparatus 1 includes a first flattening module 101 and a second flattening module 102, which are sequentially disposed at one side of the conveying line. The first leveling module 101 levels a left tab of the battery cell, and the second leveling module 102 levels a right tab of the battery cell, or vice versa in actual operation. The first flattening module 101 and the second flattening module 102 may be identical in structure or different in structure, and generally, the same structure is adopted, and the flattening apparatus will be described below with reference to a specific structure.

Fig. 2 is a schematic structural diagram of a leveling device in the cell tab leveling, detecting and cutting system according to the present invention in an exemplary embodiment. As shown in fig. 2, the cell tab leveling device in this embodiment includes more than one, for example, two, leveling modules.

In this embodiment, each leveling module includes a frame body 11, a bearing table 12, a pressing head 13, and a driving mechanism 14. Wherein, the frame body 11 is fixedly arranged and can comprise a vertical plate and a transverse plate which are connected to form a supporting structure.

In this embodiment, the bearing table 12 is adjustably mounted on the frame 11, and the battery cell is carried on the bearing surface of the bearing table 12. Fig. 3 is an enlarged schematic view of the shielding plate of fig. 2 with a portion removed. Fig. 3 shows a specific structure of the carrier table 12 in this embodiment.

In this embodiment, the carrier stage 12 includes an upper carrier stage 121, a middle carrier stage 122, and a lower carrier stage 123. The middle stage 122 is disposed between the upper stage 121 and the lower stage 123 and can be withdrawn, and the upper stage 121 can move up and down relative to the lower stage 123 after the middle stage 122 is withdrawn.

Specifically, the intermediate support platform 122 is drivingly connected to a traverse cylinder 124, and the traverse cylinder 124 can drive the intermediate support platform 122 to move horizontally. In addition, a slide rail is disposed on the upper bearing surface of the lower bearing platform 123, and the middle bearing platform 122 moves along the slide rail.

In this embodiment, an adjusting cylinder 125 is further connected between the upper bearing platform 121 and the lower bearing platform 123, a cylinder body of the adjusting cylinder 125 is mounted on the lower bearing platform 123, and a piston of the adjusting cylinder 125 is connected to the upper bearing platform 121. The two adjustment cylinders 125 are provided symmetrically in the left-right direction.

In this embodiment, the lower stage 123 is connected to the moving-out mechanism 15 in a transmission manner, and the moving-out mechanism 15 can drive the lower stage 123 to move out. Specifically, the removing mechanism 15 includes a removing nut 151, a removing screw 152 and a motor 153, the motor 153 is in transmission connection with the removing screw 152, the removing screw 152 is in fit connection with the removing nut 151, and the removing nut 151 is mounted on the lower bearing table 123.

In this embodiment, the carriers 12 of the first leveling module 101 and the second leveling module 102 are arranged side by side, and the two carriers 12 are mounted side by side on a single base. In addition, in order to conveniently move out the bearing tables 12, sliding rails are arranged between the two bearing tables 12 and the base.

In this embodiment, the pressure head 13 is disposed corresponding to an upper bearing surface of an upper bearing table 121 of the bearing table 12, and the tabs of the battery cell placed on the bearing surface are flattened by the cooperation of the bearing surface. In this embodiment, the ram 13 is a block-like structure.

In this embodiment, the driving mechanism 14 is drivingly connected to the ram 13, and drives the ram 13 to move in the vertical direction of the frame 11. The driving mechanism 14 includes a pneumatic/hydraulic pressurizing cylinder 141 to increase the driving force and ensure the pressure.

The operation of this example is as follows:

at the first moment, the middle carrier 122 is moved out, the upper carrier 121 is directly pressed on the lower carrier 123, and the upper carrier 121 is lower than the conveying surface of the conveying line 4. When the battery cell is transmitted, the adjusting cylinder 125 acts to prop up the upper bearing table 121, so that the upper bearing surface of the upper bearing table 121 is gradually higher than the conveying surface of the conveying line 4, and the battery cell enters the upper bearing surface of the upper bearing table 121 from the conveying line 4. After the specified height is reached, the adjusting cylinder 125 stops acting, the traversing cylinder 124 acts to push the middle bearing platform 122 to move along the slideway, and the middle bearing platform 121 and the lower bearing platform 123 enter a space between the upper bearing platform 121 and the lower bearing platform 123, and the adjusting cylinder 125 releases pressure, so that the upper bearing platform 121, the middle bearing platform 122 and the lower bearing platform 123 are pressed up and down in sequence. Then the driving mechanism 14 acts to drive the driving head 13 to press the tab of the cell downwards. After the flattening operation is completed, the driving mechanism 14 drives the pressing head 15 to move upward, the adjusting cylinder 125 supports the upper bearing table 121, and the traverse cylinder 124 drives the middle bearing table 122 to move out. Finally, the adjustment cylinder 125 is depressurized and the upper bearing platform 121 presses against the lower bearing platform 123 again, completing a cycle.

In this embodiment, the detection device 2 is disposed on one side of the conveying line 4 and located downstream of the leveling device 1, and performs electrical detection on the tab of the battery cell, where the detection content includes open-circuit voltage and/or internal resistance.

Fig. 4 is a schematic structural diagram of a detection device in the cell tab flattening, detecting and cutting system according to the present invention in an exemplary embodiment. As shown in fig. 4, the inspection apparatus in this embodiment includes a base 21, a guide post 22, a first bracket 23 and a second bracket 24, and an inspection table 25 and an inspection structure 26. The base 21 is fixed, and is usually fixed by anchor screws.

In this embodiment, the guide posts 22 are installed on the base 21, and are two in total and arranged symmetrically left and right, and the guide posts 22 are polished rods with smooth surfaces.

In this embodiment, the first bracket 23 and the second bracket 24 are each movably mounted on the guide post 22.

In this embodiment, the test platform 25 is mounted on the first support 23, and the test structure 26 is mounted on the second support 24 and is disposed corresponding to the test platform 25. Wherein the sensing structure 26 includes either or both of a sensing probe and a stylet in this embodiment.

In this embodiment, the test platform 25 is mounted on an adjustment plate 251, and the adjustment plate 251 is adjustably mounted on the first support 23 through the elongated hole. The adjusting plate 251 has an L-shaped structure, a supporting cylinder 252 is mounted on a supporting portion of the adjusting plate 251, and a piston of the supporting cylinder 252 is connected to the detecting table 25. The support cylinder 252 in this embodiment has a plurality of pistons arranged in parallel with each other.

In this embodiment, the second bracket 24 is located at an upper portion of the first bracket 23, and a lifting mechanism 27 is connected to enable the second bracket 24 to move up and down along the guide post 22. The lifting mechanism 27 includes a lifting cylinder 271 and a connecting plate 272, wherein one end of the connecting plate 272 is connected to the piston of the lifting cylinder 271, and the other end is connected to the second support 24.

In this embodiment, the detecting device 2 further comprises an adjusting structure 28, the adjusting structure 28 is adjustably mounted on the second bracket 24, and the detecting structure 26 is mounted on the adjusting structure 28. In this embodiment, the detecting device 2 further comprises a driving cylinder 29, the cylinder body of the driving cylinder 29 is mounted on the adjusting structure 28, and the piston is connected with the detecting structure 26. Specifically, the adjusting structure 28 includes a vertical column and an adjusting platform, the adjusting platform is provided with a strip-shaped adjusting hole, and the driving cylinder 29 is adjustably installed in the adjusting hole in a matching manner through a connecting plate.

In this embodiment, the height of the detection table 25 is equivalent to the conveying surface of the conveying line 4, and the passing battery cell can be detected. If the specifications of the battery cells are changed, the height of the detection platform 25 can be adjusted through the lifting mechanism 27, and the horizontal detection position of the detection structure 26 can be adjusted through the adjusting structure 28. In addition, the detection table 25 can also perform fine adjustment on the horizontal and vertical positions through the adjusting plate 251 and the supporting cylinder 252 so as to adapt to the detection requirements of the battery cells with different specifications.

Fig. 5 is a schematic structural diagram of a cutting device in the cell tab flattening, detecting and cutting system according to the present invention in an exemplary embodiment. In this embodiment, as shown in fig. 5, a cutting device 3 is disposed at one side of the conveying line 4 and downstream of the detecting device 2, and is used for cutting the tab of the battery cell.

The cutting device 3 of this embodiment includes a frame body 31, a mounting plate 32, a first cutter 33, a second cutter 34, a driving mechanism 35, a first lifting mechanism 36, a second lifting mechanism 37, a first connecting plate 38, and a second connecting plate 39. The frame body 31 includes a straight plate and two reinforcing plates, the moving guide rails 311 are disposed on one side of the straight plate, and the two reinforcing plates are symmetrically connected to the other side of the straight plate.

In this embodiment, the mounting plate 32 is slidably mounted on the moving rail 311, the first connecting plate 38 and the second connecting plate 39 are slidably engaged with the mounting plate 32, the first lifting mechanism 36 is in transmission connection with the first cutter 33 and drives the first cutter 33 to move in the vertical direction of the mounting plate 32, and the second lifting mechanism 37 is in transmission connection with the second cutter 34 and drives the second cutter 34 to move in the vertical direction of the mounting plate 32.

In a more specific structure, one end of the first connecting plate 38 is connected with the first cutter 33, the other end is in transmission connection with the first lifting mechanism 36, one end of the second connecting plate 39 is connected with the second cutter 34, and the other end is in transmission connection with the second lifting mechanism 37.

In a more specific structure, the first lifting mechanism 36 includes a first lifting cylinder 361, the second lifting mechanism 37 includes a second lifting cylinder 371, the cylinder bodies of the first lifting cylinder 361 and the second lifting cylinder 371 are both installed on the mounting plate 32, the piston of the first lifting cylinder 361 is in transmission connection with the first connecting plate 38, and the piston of the second lifting cylinder 371 is in transmission connection with the second connecting plate 39.

In another more specific structure, the second connecting plate 39 is connected with side plates 372 at both sides thereof, and the side plates 372 are located at the outer side of the first connecting plate 38 to pass through the first connecting plate 38 and be connected with a second lifting cylinder 371 in the second lifting mechanism 37 located above the first connecting plate 38, so as to realize the transmission connection between the second lifting mechanism 36 and the second cutter 34.

In this embodiment, the first cutter 33 and the second cutter 34 are slidably mounted on the mounting plate 32 at corresponding positions. The first cutter 33 is located above the second cutter 34, and the first cutter 33 and the second cutter 34 are staggered and bisected. The first cutting knife 33 is provided with an elastic pressing structure 331, and the elastic pressing structure 331 protrudes below the first cutting knife 33 in a non-compressed state and retracts above the first cutting knife 33 in a compressed state. In practice, it is also possible to install an elastic capping structure on the second cutter 34, wherein the capping direction is opposite.

Specifically, fig. 6 is a schematic diagram of an elastic capping structure in the cell tab flattening, inspecting and trimming system of the present invention shown in an exemplary embodiment. As shown in fig. 6, the elastic pressing structure 331 includes a pressing head 3311, a guide plate 3312, a guide post 3313, and a spring 3314. The pressing head 3311 and the guide plate 3312 are connected via a guide post 3313, and have a certain distance therebetween and are axially movable relative to each other, and a spring 3314 is sleeved on the guide post 3313 and clamped between the pressing head 3311 and the guide plate 3312 to elastically compress the pressing head 3311 and the guide plate 3312.

In this embodiment, the driving mechanism 35 is drivingly connected to the mounting plate 32 and drives the mounting plate 32 to move in the vertical direction of the frame body 31. In this embodiment, the driving mechanism 35 includes a driving cylinder, a cylinder 351 of the driving cylinder is fixedly mounted on the upper portion of the frame body 31, and a piston 352 of the driving cylinder is in transmission connection with the upper end of the mounting plate 32 to drive the mounting plate 32 to move along the vertical direction of the frame body.

In this embodiment, the cutting device 3 further includes a sliding base 30, and the frame body 31 is mounted on the sliding base 30. In the specific structure of this embodiment, the sliding base 30 includes a fixing base 301, an adjustment guide 302, a sliding block 303, and a driving member 304. Wherein, support body 31 installs on slider 303, and fixing base 301 is fixed to be set up, adjusts guide rail 302 and installs on fixing base 301, and slider 303 cooperates with adjusting guide rail 302, and driving piece 304 transmission link slider 303, and drive slider 303 moves on adjusting guide rail 302. The fixing base 301 may be fixed by a ground screw or an embedded part. The drive member 304 may be an electric motor, a pneumatic cylinder, a hydraulic cylinder, or a motor, among others. In addition, a position limiting plate 305 is optionally provided in this embodiment, and the position limiting plate 305 is located at one end of the adjustment rail 302 to limit the movement of the slider 303.

The first cutter 33 and the second cutter 34 in this embodiment can both move along the mounting plate 32, so that the cutting position is more flexible, and the cutting device is suitable for cutting tabs of battery cells with more specifications.

Fig. 7 is a schematic structural diagram of another cutting device in the cell tab flattening, detecting and cutting system according to the present invention in an exemplary embodiment. As shown in fig. 7, the cutting device 5 of this embodiment is disposed on one side of the conveying line 4 and downstream of the detecting device 2, and is used for cutting the tab of the battery cell.

The cutting device 5 of this embodiment includes a holder body 51, a first cutter 52, a second cutter 53, and a drive mechanism 54. As in the previous embodiment, the frame 51 is provided with a moving guide 511, and other structures are not described again.

In this embodiment, the first cutter 52 is slidably mounted on the moving rail 511, and the second cutter 53 is fixedly mounted on the frame body 51 and located at the lower end of the moving rail 511, and is disposed corresponding to the first cutter 52. The driving mechanism is in transmission connection with the first cutter 52 and drives the first cutter 52 to move in the vertical direction of the frame body 51. In this embodiment, the first cutter 52 is located above the second cutter 53, and the first cutter 52 and the second cutter 53 are staggered and bisected.

In this embodiment, the first cutting blade 52 is provided with a resilient pressing structure 522, and the resilient pressing structure 522 protrudes below the first cutting blade 52 in the non-compressed state and retracts above the first cutting blade 52 in the compressed state. The elastic pressing structure 522 is the same as the previous embodiment in structure, and includes a pressing head, a guide plate, a guide post and a spring, the pressing head and the guide plate are connected through the guide post and can move axially relative to each other, and the spring is sleeved on the guide post and clamped between the pressing head and the guide plate. The specific structure is shown in fig. 6, and is combined with the discussion of the previous embodiment.

In this embodiment, the battery tab cutting device further includes a mounting plate 521, one end of the mounting plate 521 is connected to the first cutter 52, the other end of the mounting plate 521 is connected to the driving mechanism 54 in a transmission manner, and the mounting plate 521 is in sliding fit with the moving guide rail 511. The driving mechanism 54 includes a cylinder, a cylinder body 541 of the cylinder is fixedly installed on the frame body 51, and a piston 542 of the cylinder is in transmission connection with the upper end of the mounting plate 521.

In this embodiment, the cutting device 5 further includes a guide seat 55, a guide rod 56 is disposed on the guide seat 55, a guide hole is disposed on the mounting plate 521, and the guide rod 56 is slidably engaged with the guide hole.

In this embodiment, the cutting device 5 further includes a sliding base 50, and the frame body 51 is mounted on the sliding base 50, as in the previous embodiment. Similarly, the sliding base 50 includes a fixed seat 501, an adjusting guide rail 502, a sliding block 503 and a driving member 504, the frame body 51 is installed on the sliding block 503, the fixed seat 501 is fixedly arranged, the adjusting guide rail 502 is installed on the fixed seat 501, the sliding block 503 is matched with the adjusting guide rail 502, the driving member 504 is in transmission connection with the sliding block 503, and the driving block 503 is driven to move on the adjusting guide rail 502. In view of the same structure as the previous embodiment, the other contents are not described again.

The second cutter 53 in this embodiment is fixed, so the cutting is more accurate and powerful, and the cutting tool is suitable for cutting the tab of the battery cell with a larger specification.

In this embodiment, the conveying line 4 sequentially and automatically conveys the battery core through the flowing water, when passing through the leveling device 1, the first leveling module 101 and the second leveling module 102 respectively level two tabs of the battery core, the electrical property of the battery core is detected when passing through the detection device 2, and the tabs of the battery core are cut when passing through the cutting device 3 or 5. Whole in-process, the transport of electric core is incessant, and the flattening of electric core utmost point ear, detection and cutting are automatic going on moreover, need not artifical the intervention, have realized full automation line production, improve the efficiency of electric core production equipment greatly.

In addition, in the above embodiments, various structures that are parallel to each other may still be combined in a cross manner to form a plurality of different technical solutions, and due to space limitation, the combination of the technical solutions cannot be exhaustive, but any combination thereof is still within the disclosure range of the present patent.

It should be understood by those of ordinary skill in the art that the specific constructions and processes illustrated in the foregoing detailed description are exemplary only, and are not limiting. Furthermore, the various features shown above can be combined in various possible ways to form new solutions, or other modifications, by a person skilled in the art, all falling within the scope of the present invention.

Claims (7)

1. The utility model provides an electricity core utmost point ear flattening, detection and cutting system for carry out flattening, detection and cutting to the utmost point ear of electric core, its characterized in that includes:

the conveying line conveys the battery cell through a jig:

the leveling device comprises a first leveling module and a second leveling module which are sequentially arranged on one side of the conveying line, and the first leveling module and the second leveling module respectively level two pole lugs of the battery cell one by one;

the detection device is arranged on one side of the conveying line, is positioned at the downstream of the leveling device and is used for electrically detecting the lug of the battery cell;

the cutting device is arranged on one side of the conveying line, is positioned at the downstream of the detection device and is used for cutting the electrode lug of the battery cell;

the two leveling modules are arranged on a base in parallel in a sliding mode, and each leveling module comprises a leveling module body;

the rack body is fixedly arranged;

the battery cell is supported on a bearing surface of the bearing table, the bearing table comprises an upper bearing table, a lower bearing table and a middle bearing table, the middle bearing table is arranged between the upper bearing table and the lower bearing table and can be withdrawn, the upper bearing table can move up and down relative to the lower bearing table after the middle bearing table is withdrawn, the middle bearing table is in transmission connection with a transverse moving cylinder, the transverse moving cylinder can drive the middle bearing table to move horizontally, an adjusting cylinder is further connected between the upper bearing table and the lower bearing table, a cylinder body of the adjusting cylinder is mounted on the lower bearing table, and a piston of the adjusting cylinder is connected with the upper bearing table;

the pressure head is arranged corresponding to the bearing table;

and the driving mechanism is in transmission connection with the pressure head and drives the pressure head to move in the vertical direction of the frame body.

2. The system for leveling, detecting and cutting a battery cell tab of claim 1, wherein the lower carrier is drivingly connected to a removal mechanism, the removal mechanism is capable of driving the lower carrier to move out, the removal mechanism comprises a removal nut, a removal screw and a motor, the motor is drivingly connected to the removal screw, the removal screw is cooperatively connected to the removal nut, and the removal nut is mounted on the lower carrier.

3. The battery tab leveling, testing and trimming system of claim 1, wherein the testing device comprises:

the base is fixedly arranged;

a guide post mounted on the base;

a first bracket and a second bracket, both movably mounted on the guide post;

detect the platform and detect the structure, it installs to detect the platform on the first support, it installs to detect the structure on the second support, and correspond detect the platform setting.

4. The battery tab leveling, testing and trimming system of claim 3 wherein the test station is mounted on a tuning plate adjustably mounted to the first support by way of the elongated aperture.

5. The battery tab leveling, inspecting and trimming system of claim 3, wherein the second support is located on top of the first support and has a lifting mechanism attached to it to enable the second support to move up and down along the guide posts.

6. The cell tab leveling, sensing and trimming system of claim 1, wherein the trimming means comprises:

the rack body is provided with a movable guide rail;

the mounting plate is slidably mounted on the moving guide rail;

the first cutter is slidably mounted on the mounting plate;

the second cutter is slidably mounted on the mounting plate and is arranged corresponding to the first cutter;

the driving mechanism is in transmission connection with the mounting plate and drives the mounting plate to move in the vertical direction of the rack body;

the first lifting mechanism is in transmission connection with the first cutter and drives the first cutter to move in the vertical direction of the mounting plate;

and the second lifting mechanism is in transmission connection with the second cutter and drives the second cutter to move in the vertical direction of the mounting plate.

7. The cell tab leveling, sensing and trimming system of claim 1, wherein the trimming means comprises:

the rack body is provided with a movable guide rail;

the first cutter is slidably mounted on the movable guide rail;

the second cutter is fixedly arranged on the frame body and is arranged corresponding to the first cutter;

and the driving mechanism is in transmission connection with the first cutter and drives the first cutter to move in the vertical direction of the rack body.

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