CN108155428B - Code scanning device for testing cylindrical battery cell - Google Patents

Abstract

The invention provides a code scanning device for testing a cylindrical battery cell, which comprises: the cylindrical test scanning device comprises a profiling strip, a translation mechanism, a battery core overturning mechanism, a battery core rolling mechanism, a testing mechanism and a code scanner, wherein when the cylindrical test scanning device is used, firstly the battery core overturning mechanism rotates a cylindrical battery core to the horizontal direction to prevent the cylindrical battery core from being arranged on the profiling strip, then the cylindrical battery core is sent to a detection mechanism through the translation mechanism to detect the cylindrical battery core, after detection, the cylindrical battery core is moved to the battery core rolling mechanism through the translation mechanism, the cylindrical battery core is driven to roll through the battery core rolling mechanism, and meanwhile, a bar code on the surface of the cylindrical battery core is scanned through the scanner. The code scanning device for testing the cylindrical battery cells can simultaneously realize multiple procedures, reduce time, simultaneously test a plurality of battery cells for scanning codes, and has high code scanning efficiency, and is particularly suitable for automatic production lines of round battery cells and the like.

Description

Code scanning device for testing cylindrical battery cell

Technical Field

The invention relates to the technical field of automatic equipment of cylindrical battery cells, in particular to a code scanning mechanism for testing cylindrical battery cells.

Background

Due to the continual pursuit of sustainable and clean energy by humans, traditional petrochemical energy has failed to meet the needs of people. The new energy battery is used as a clean energy source, has the advantages of high efficiency, cleanness, safety, reliability and the like, and becomes a hot spot for energy development at present. With the rapid development of new energy industry, cylindrical battery cells are used as the most commonly used battery cells, and are widely applied to the fields of new energy electric automobiles, notebook computers, electric tools and the like.

In order to verify the performance of the cylindrical battery cell before delivery, voltage and internal resistance tests are required to be carried out on the cylindrical battery cell. In order to distinguish each cylindrical cell, a scan code is usually set on the cylindrical cell, and the scan code is required to be scanned before the cylindrical cell leaves the factory. At present, the testing and code scanning of most manufacturers are finished through different devices, the efficiency is low, the cost is high, and therefore, an integrated device capable of realizing the simultaneous testing and scanning is needed to be designed, so that the working efficiency is improved.

Disclosure of Invention

In view of the above-mentioned drawbacks of the prior art, the present invention aims to provide a device for scanning a test code of a cylindrical battery cell, which can perform test and scanning simultaneously.

To achieve the above and other related objects, the present invention provides a device for scanning a test code of a cylindrical battery cell, comprising: the inner sides of the profiling strips are provided with at least one supporting groove corresponding to the shape of the cylindrical battery cell, and the two profiling strips are used for supporting two ends of the cylindrical battery cell; the translation mechanism comprises a jacking plate, at least one profiling groove is formed in the jacking plate, the jacking plate is located between two profiling strips, and the jacking plate can move up and down and left and right between the two profiling strips; the battery cell turnover mechanism comprises a rotating plate, a battery cell fixing seat is arranged on the rotating plate, a battery cell fixing groove is formed in the battery cell fixing seat, the rotating plate is connected with a rotating cylinder, the rotating cylinder can drive the rotating plate to rotate, a magnet mounting hole is formed in the battery cell fixing seat, a magnet capable of moving back and forth is arranged in the magnet mounting hole, and the magnet is connected with a first cylinder; the battery cell rolling mechanism comprises two belt pulley groups, wherein each belt pulley group comprises a first belt pulley, a second belt pulley and a driving motor, the first belt pulley and the second belt pulley are connected through a belt, the belt pulley groups are positioned between two profiling strips, the belt pulley groups can move up and down, the jacking plate can move up and down, left and right between the two belt pulley groups, and the first belt pulley or the second belt pulley is connected with the driving motor; the testing mechanism is used for testing the cylindrical battery cell and is positioned on the outer side of one profiling strip; the code scanner is positioned above the battery cell rolling mechanism, and the code scanner is used for scanning the bar code on the cylindrical battery cell.

Preferably, the translation mechanism comprises a sliding rail, a sliding block is arranged on the sliding rail and connected with a moving plate, the moving plate is connected with a second air cylinder through a connecting plate, the second air cylinder drives the moving plate and the sliding block to move on the sliding rail, a third air cylinder is arranged on the moving plate and connected with a jacking plate, and the third air cylinder drives the jacking plate to move up and down.

Preferably, buffer mounting seats are arranged on two sides of the sliding rail, and a buffer is arranged on each buffer mounting seat.

Preferably, the electric core rolling mechanism comprises two parallel wheel set supporting plates, wherein a wheel set mounting plate is arranged on each wheel set supporting plate and is in sliding connection with the wheel set supporting plate, the wheel set mounting plate is connected with a fourth air cylinder, the fourth air cylinder can drive the wheel set mounting plate to move up and down, and the two belt pulleys are respectively arranged on the two wheel set mounting plates of the wheel set supporting plates.

Preferably, a fifth air cylinder is arranged on the wheel set mounting plate and connected with the battery cell guard plate, and the fifth air cylinder can drive the battery cell guard plate to move up and down.

Preferably, a linear sliding rail is arranged between the wheel set supporting plate and the wheel set mounting plate.

Preferably, the fourth cylinder is connected with the wheel set mounting plate through an L-shaped connecting plate.

Preferably, the testing mechanism comprises a probe supporting plate, a sixth air cylinder is arranged on the probe supporting plate and connected with the integrated panel, a probe support is arranged on the integrated panel, and a testing probe is arranged on the probe support.

Preferably, the rotating plate is provided with an inductor for inducing whether a cylindrical battery cell exists, and the inductor corresponds to the battery cell fixing seat one by one.

Preferably, the device further comprises a frame, and the profiling strip, the battery core overturning mechanism, the translation mechanism, the battery core rolling mechanism, the testing mechanism and the scanner are fixed on the frame.

As described above, the code scanning device for testing the cylindrical battery cell has the following beneficial effects: when the cylindrical test scanning device is used, firstly, the battery core turnover mechanism rotates the cylindrical battery core to the horizontal direction to prevent the cylindrical battery core from being on the profiling strip, then the cylindrical battery core is conveyed to the detection mechanism through the translation mechanism to detect the cylindrical battery core, after detection is completed, the cylindrical battery core is moved to the battery core rolling mechanism through the translation mechanism, the cylindrical battery core is driven to roll through the battery core rolling mechanism, and meanwhile, the bar code on the surface of the cylindrical battery core is scanned through the scanner. The code scanning device for testing the cylindrical battery cells can simultaneously realize multiple procedures, reduce time, simultaneously test a plurality of battery cells for scanning codes, and has high code scanning efficiency, and is particularly suitable for automatic production lines of round battery cells and the like.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present invention;

FIG. 2 is a schematic diagram of the internal structure of an embodiment of the present invention;

FIG. 3 is a schematic view of a profile strip according to an embodiment of the present invention;

FIG. 4 is a schematic view of a translation mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a battery cell turnover mechanism according to the present invention;

FIG. 6 is a schematic diagram of a cell rolling mechanism according to an embodiment of the present invention;

FIG. 7 is a schematic diagram of a single side of a cell rolling mechanism according to an embodiment of the present invention;

fig. 8 is a schematic structural diagram of a testing mechanism according to an embodiment of the invention.

Description of element numbers: 1. an equipment mounting plate; 2. the battery core overturning mechanism; 3. a frame; 4. a translation mechanism; 5. a testing mechanism; 6. a battery core rolling mechanism; 7. profiling strips; 8. a buffer; 9. a buffer mount; 10. a profiling strip support plate; 11. reinforcing ribs; 12. a code scanner; 13. a support rod; 14. a rotating bracket; 15. a rotary cylinder; 16. a rotating plate; 17. the battery cell fixing seat; 18. a magnet; 19. a rotating plate support frame; 20. an inductor; 21. a first cylinder; 22. a first cylinder mounting plate; 23. a slide rail; 24. a slide block; 25. a moving plate; 26. a connecting plate; 27. a second cylinder; 28. a jacking plate; 29. a third cylinder; 30. a simulated groove; 31. a bottom mounting plate; 32. rib plates; 33. a second cylinder mounting plate; 34. a sixth cylinder; 35. an adapter plate; 36. an integrated panel; 37. a probe mounting rack; 38. a probe linker; 39. a probe; 40. a cover plate; 41. a bottom fixing plate; 42. a fourth cylinder; 43. a wheel set support plate; 44. a linear slide rail; 45. a rotating seat; 46. a first rotation shaft; 47. a first pulley; 48. a belt; 49. a second rotation shaft; 50. a wheel set mounting plate; 51. a coupling; 52. a motor mounting plate; 53. a driving motor; 54. a second pulley; 55. adjusting the block; 56. locking nails; 57. a cell guard board; 58. a fifth cylinder; 59. an L-shaped connecting plate; 60. a motor support plate; 61. and a support groove.

Detailed Description

Further advantages and effects of the present invention will become apparent to those skilled in the art from the disclosure of the present invention, which is described by the following specific examples.

Please refer to fig. 1 to 8. It should be understood that the structures, proportions, sizes, etc. shown in the drawings are for illustration purposes only and should not be construed as limiting the invention to the extent that it can be practiced, since modifications, changes in the proportions, or otherwise, used in the practice of the invention, are not intended to be critical to the essential characteristics of the invention, but are intended to fall within the spirit and scope of the invention. Also, the terms such as "upper," "lower," "left," "right," "middle," and "a" and the like recited in the present specification are merely for descriptive purposes and are not intended to limit the scope of the invention, but are intended to provide relative positional changes or modifications without materially altering the technical context in which the invention may be practiced.

As shown in fig. 1, the invention provides a cylindrical battery cell testing code scanning device, which comprises a frame 3, wherein an equipment mounting plate 1 is arranged on the frame 3, a translation mechanism 4, a testing mechanism 5 and a battery cell rolling mechanism 6 are arranged on the equipment mounting plate 1, two sides of the equipment mounting plate are respectively provided with a profiling strip supporting plate 10, and two profiling strips 7 which are arranged in parallel are arranged on the profiling strip supporting plate 10. As shown in fig. 3, the profiling strip 7 is provided with a supporting groove 61, and two profiling strips are used for supporting two ends of the cylindrical battery cell. And a battery core overturning mechanism 2 is further arranged on one profiling strip supporting plate 10, and the battery core overturning mechanism is positioned above the profiling strip 7. The device mounting plate 1 is also provided with a supporting rod 13, the supporting rod 13 is provided with a scanner 12, and the scanner 12 is positioned above the battery cell rolling mechanism 6.

As shown in fig. 2, the translation mechanism 4 includes a lifting plate 28, at least one profiling groove 30 is provided on the lifting plate 28, the lifting plate 28 is located between the two profiling strips 7, and the lifting plate 28 can move up and down and left and right between the two profiling strips. When the electric core copying machine is used, the cylindrical electric cores are placed on the two copying strips 7, the lifting plate 28 firstly lifts up to lift up the cylindrical electric cores, then the lifting plate 28 moves in the horizontal direction, when the electric core copying machine moves to a designated position, the lifting plate 28 moves downwards, and then the cylindrical electric cores are placed on the copying strips 7, so that the cylindrical electric cores can be moved on the copying strips 7.

As shown in fig. 4, as a specific embodiment, the translation mechanism 4 is provided with a slide rail 23, a slide block 24, a moving plate 25, a connecting plate 26, a second cylinder, a lifting plate 28, and a third cylinder 29. A connecting plate 26 is arranged on the second air cylinder 27, the connecting plate 26 is fixedly arranged on the moving plate 25, a sliding block 24 is arranged below the moving plate 25, and the sliding block 24 is arranged on the sliding rail 23; the second cylinder 27 drives all parts on the connecting plate 26 and the moving plate 25 to horizontally move on the slide rail 23. The jacking plate 28 is connected with a third air cylinder 29, and the third air cylinder 29 drives the jacking plate 28 and all parts on the jacking plate to vertically move up and down. Buffer mounting seats 9 are arranged on two sides of the sliding rail 23, and a buffer 8 is arranged on each buffer mounting seat 9.

As shown in fig. 5, the battery core turning mechanism 2 is provided with a rotary bracket 14, a rotary cylinder 15, a rotary plate 16, a battery core fixing seat 17, a magnet 18, a supporting frame 19, an inductor 20, a cylinder 21 and a first cylinder mounting plate 22; the rotating plate 16 is supported between the rotating bracket 14 and the supporting frame 19, the rotating plate 16 is rotatable, a battery core fixing seat 17, a cylinder mounting plate 22 and an inductor 20 are mounted on the rotating plate 16, and a battery core fixing groove is formed in the battery core fixing seat. The rotary cylinder 15 drives the rotary plate 16 and parts thereon to rotate together around the rotary axis of the rotary cylinder 15 and the support 19 through rotation, and the rotary plate 16 is hinged with the support 19.

The first cylinder mounting plate 22 is provided with a first cylinder 21, the battery cell fixing seat 17 is internally provided with a magnet mounting hole, the magnet mounting hole is internally provided with a magnet 18 capable of moving back and forth, the magnet 18 is connected with the front end of the first cylinder 21, the first cylinder 21 can push the magnet 18 to move back and forth in a hole between the rotating plate 16 and the battery cell fixing seat 17, and the cylindrical battery cell is adsorbed on the battery cell fixing seat 17 through the magnet 18. The sensor 20 mounted on the rotating plate 16 can be used for detecting whether the battery core is arranged on the battery core fixing seat 17, and the sensor corresponds to the position of the battery core fixing seat one by one.

When the battery core turnover mechanism 2 is used, a cylindrical battery core is firstly arranged in a magnet mounting hole of a battery core fixing seat 17 in a vertical state, the cylindrical battery core is fixed under the suction effect of a magnet 18, then a rotary cylinder 15 drives a rotary plate 16 to rotate 90 degrees, at the moment, the cylindrical battery core is rotated to the horizontal direction and is positioned above a profiling strip 7, a first cylinder 21 is retracted backwards, so that the magnet 18 is far away from the cylindrical battery core, and the cylindrical battery core falls off from the battery core fixing seat 17 and falls into a supporting groove of the profiling strip 7.

As shown in fig. 8, the test mechanism 5 is provided with a bottom surface mounting plate 31, a rib plate 32, a second cylinder mounting plate 33, a sixth cylinder 34, an adapter plate 35, an integrated panel 36, a probe mount 37, a probe connector 38, a probe 39, and a cover plate 40. The sixth cylinder 34 is mounted on the second cylinder mounting plate 33, the adapter plate 35 is mounted on the sixth cylinder 34, the integrated panel 36 is mounted on the adapter plate 35, the probe mount 37 is mounted on the integrated panel 36, the probe connector 38 is mounted on the probe mount 37, and the probe 39 is mounted on the probe connector 38. The test mechanism 5 is located outside one profiling strip 7, the profiling strip 7 is provided with a test hole corresponding to the position, the translation mechanism firstly sends the cylindrical battery cell to the corresponding test position, the sixth cylinder 34 drives the adapter plate 35 and all parts on the adapter plate to horizontally move, the probe 39 is pushed to be contacted with the battery cell electrode, and the probe 39 is connected with the test instrument, so that the voltage and the resistance of the cylindrical battery cell are tested.

As shown in fig. 1, 2, 6 and 7, the battery cell rolling mechanism 6 comprises two parallel wheel set support plates 43, the wheel set support plates 43 are fixed on the device mounting plate 1 through bottom fixing plates 41, wheel set mounting plates 50 are arranged on the wheel set support plates 43, the wheel set mounting plates 50 are slidably connected with the wheel set support plates 43 through linear sliding rails 44, and the wheel set mounting plates 50 are connected with fourth air cylinders 42 through L-shaped connecting plates 59. Fourth cylinder 42 may drive wheel set mounting plate 50 up and down. Each pulley group mounting plate 50 is provided with a pulley group, each pulley group comprises a first pulley 47, a second pulley 54 and a driving motor 53, the first pulley 47 and the second pulley 54 are connected through a belt 48, the pulley group is positioned between two profiling strips, the pulley group can move up and down, and the jacking plate 28 can move up and down and left and right between the two pulley groups.

As a specific embodiment, the wheel set mounting plate 50 is provided with a rotating seat 45, the first rotating shaft 46 is mounted on the rotating seat 45, the first rotating shaft 46 can rotate in the rotating seat 45, and the first rotating shaft 46 is provided with a first belt wheel 47. The motor supporting plate 60 is provided with a motor mounting plate 52, the motor mounting plate 52 is provided with a driving motor 53, the driving motor 53 is connected with a second rotating shaft 49 through a coupler 51, the second rotating shaft 49 is provided with a second belt wheel 54, a belt 48 is connected between the first belt wheel 47 and the second belt wheel 54, and the driving motor 53 drives the second belt wheel 54 to rotate, so that the belt 48 and the first belt wheel 47 are driven to rotate. The adjustment block 55 and the locking pin 56 can finely adjust the position of the swivel mount.

When the battery cell rolling mechanism 6 is used, the cylindrical battery cells can be firstly conveyed into the supporting grooves of the profiling strips above the belt 48 through the translation mechanism, then the wheel set mounting plate 50 is upwards driven by the fourth air cylinder 42 to upwards move, so that the belt is in contact with the cylindrical battery cells, meanwhile, the belt 48 is driven by the driving motor 53 to move, and under the action of friction force, the cylindrical battery cells can rotate, and thus, the bar codes on the peripheral surfaces of the cylindrical battery cells can be scanned through the scanner above. The upward displacement of the fourth air cylinder 42 should not be too great to ensure that the cylindrical cells do not disengage from the support slots. In order to prevent the battery cell from being separated from the supporting groove, a fifth air cylinder 58 is arranged on the wheel set mounting plate 50, the fifth air cylinder 58 is connected with the battery cell guard plate 57, and the fifth air cylinder 58 can drive the battery cell guard plate 57 to move up and down. The battery cell guard 57 is driven by the air cylinder six 58 to move up and down, and the battery cell guard 57 descends when the battery cell rotates, so that the battery cell can be prevented from moving left and right when the battery cell rotates.

When the cylindrical test scanning device is used, firstly, the battery core turnover mechanism rotates the cylindrical battery core to the horizontal direction to prevent the cylindrical battery core from being on the profiling strip, then the cylindrical battery core is conveyed to the detection mechanism through the translation mechanism to detect the cylindrical battery core, after detection is completed, the cylindrical battery core is moved to the battery core rolling mechanism through the translation mechanism, the cylindrical battery core is driven to roll through the battery core rolling mechanism, and meanwhile, the bar code on the surface of the cylindrical battery core is scanned through the scanner. The code scanning device for testing the cylindrical battery cells can simultaneously realize multiple procedures, reduce time, simultaneously test a plurality of battery cells for scanning codes, and has high code scanning efficiency, and is particularly suitable for automatic production lines of round battery cells and the like. Therefore, the invention effectively overcomes various defects in the prior art and has high industrial utilization value.

The above embodiments are merely illustrative of the principles of the present invention and its effectiveness, and are not intended to limit the invention. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the invention. Accordingly, it is intended that all equivalent modifications and variations of the invention be covered by the claims, which are within the ordinary skill of the art, be within the spirit and scope of the present disclosure.

Claims (7)

1. The utility model provides a sign indicating number device is swept in test of cylinder electricity core which characterized in that, it includes:

the inner sides of the profiling strips are provided with at least one supporting groove corresponding to the shape of the cylindrical battery cell, and the two profiling strips are used for supporting two ends of the cylindrical battery cell;

the translation mechanism comprises a jacking plate, at least one profiling groove is formed in the jacking plate, the jacking plate is located between two profiling strips, and the jacking plate can move up and down and left and right between the two profiling strips;

the battery cell turnover mechanism comprises a rotating plate, a battery cell fixing seat is arranged on the rotating plate, a battery cell fixing groove is formed in the battery cell fixing seat, the rotating plate is connected with a rotating cylinder, the rotating cylinder can drive the rotating plate to rotate, a magnet mounting hole is formed in the battery cell fixing seat, a magnet capable of moving back and forth is arranged in the magnet mounting hole, and the magnet is connected with a first cylinder;

the battery cell rolling mechanism comprises two belt pulley groups, wherein each belt pulley group comprises a first belt pulley, a second belt pulley and a driving motor, the first belt pulley and the second belt pulley are connected through a belt, the belt pulley groups are positioned between two profiling strips, the belt pulley groups can move up and down, the jacking plate can move up and down, left and right between the two belt pulley groups, and the first belt pulley or the second belt pulley is connected with the driving motor;

the testing mechanism is used for testing the cylindrical battery cell and is positioned on the outer side of one profiling strip;

the code scanner is positioned above the battery cell rolling mechanism and is used for scanning the bar code on the cylindrical battery cell;

the translation mechanism comprises a sliding rail, a sliding block is arranged on the sliding rail and is connected with a moving plate, the moving plate is connected with a second air cylinder through a connecting plate, the second air cylinder drives the moving plate and the sliding block to move on the sliding rail, a third air cylinder is arranged on the moving plate and is connected with a jacking plate, the third air cylinder drives the jacking plate to move up and down, buffer mounting seats are arranged on two sides of the sliding rail, and a buffer is arranged on each buffer mounting seat;

the battery cell rolling mechanism comprises two parallel wheel set supporting plates, wherein a wheel set mounting plate is arranged on each wheel set supporting plate and is in sliding connection with the wheel set supporting plate, the wheel set mounting plate is connected with a fourth air cylinder, the fourth air cylinder can drive the wheel set mounting plate to move up and down, and the two belt pulleys are respectively arranged on the two wheel set mounting plates of the wheel set supporting plates.

2. The cylindrical cell testing code scanning device according to claim 1, wherein: the wheel set mounting plate is provided with a fifth air cylinder, the fifth air cylinder is connected with the battery cell guard plate, and the fifth air cylinder can drive the battery cell guard plate to move up and down.

3. The cylindrical cell testing code scanning device according to claim 1, wherein: and a linear sliding rail is arranged between the wheel set supporting plate and the wheel set mounting plate.

4. The cylindrical cell testing code scanning device according to claim 1, wherein: the fourth cylinder is connected with the wheel set mounting plate through an L-shaped connecting plate.

5. The cylindrical cell testing code scanning device according to claim 1, wherein: the test mechanism comprises a probe supporting plate, a sixth air cylinder is arranged on the probe supporting plate and connected with the integrated panel, a probe support is arranged on the integrated panel, and a test probe is arranged on the probe support.

6. The cylindrical cell testing code scanning device according to claim 1, wherein: the rotary plate is provided with an inductor for inducing whether a cylindrical battery cell exists or not, and the inductor corresponds to the battery cell fixing seat one by one.

7. The cylindrical cell testing code scanning device according to claim 1, wherein: the electric core rolling mechanism is characterized by further comprising a frame, wherein the profiling strip, the electric core overturning mechanism, the translation mechanism, the electric core rolling mechanism, the testing mechanism and the scanner are fixed on the frame.