CN216563291U - Battery side voltage testing mechanism - Google Patents

Abstract

The utility model provides a battery side voltage testing mechanism which comprises an adjusting base, a first mounting plate, a supporting assembly, a Y-axis driving assembly, a top sealing side cutting assembly and a pressing assembly, wherein the first mounting plate is vertically fixed on the adjusting base, the supporting assembly is arranged on the lower side of the first mounting plate and used for supporting a lug on a battery, the pressing assembly is arranged on the upper side of the first mounting plate and used for pressing the lug on the battery downwards, the Y-axis driving assembly is fixed on the first mounting plate, the top sealing side cutting assembly is arranged on the power output end of the Y-axis driving assembly, the Y-axis driving assembly and the top sealing side cutting assembly are respectively arranged in two groups and are respectively and symmetrically arranged on the left side and the right side of the first mounting plate.

Description

Battery side voltage testing mechanism

Technical Field

The utility model relates to the field of battery processing equipment, in particular to a battery side voltage testing mechanism.

Background

When the battery is produced, the side voltage of the battery needs to be detected, when the side voltage of the battery is detected, the two sides of the top sealing edge of the battery need to be punctured firstly, whether the battery is electrified or not is tested, if the circuit is conducted, the side voltage of the battery is detected by virtue of a test fixture, the test efficiency is low and labor force is wasted, the existing production trend of the battery is a multi-station processing full-automatic production mode, and the semi-automatic test mode cannot be applied to the production of the battery, so that a battery side voltage test mechanism needs to be manufactured, the conduction test and the side voltage test of the battery can be automatically completed, and the production efficiency is improved.

SUMMERY OF THE UTILITY MODEL

It is an object of the present invention to provide a battery side voltage testing mechanism to solve the problems mentioned in the background art.

In order to achieve the above purpose, the utility model provides the following technical scheme:

a battery edge voltage testing mechanism comprises an adjusting base, a first mounting plate, a supporting assembly, a Y-axis driving assembly, an edge sealing and cutting top assembly and a pressing assembly, wherein the first mounting plate is vertically fixed on the adjusting base;

the top sealing edge cutting assembly comprises a second mounting plate, a second Z-axis cylinder, a second sliding plate, an X-axis track plate and a cutter component, the second mounting plate is fixed at the power output end of a Y-axis driving assembly, the Y-axis driving assembly drives the second mounting plate to move front and back, the second Z-axis cylinder is fixed on the second mounting plate, the second sliding plate is fixed at the power output end of the second Z-axis cylinder and is in sliding connection with the second mounting plate, the X-axis track plate is fixed on the second sliding plate, and the cutter component is fixed on the X-axis track plate and is adjustable in position along the left and right directions.

Further description of the utility model: the cutter part includes the second connecting plate, the slip table, the fixed block, the movable block, the guide pillar, spring and cutter, the second connecting plate is fixed on X axle track board and is adjustable along controlling the direction position, the slip table is fixed on the second connecting plate, the fixed block is fixed at the rear side of slip table, the movable block is connected with the front side of slip table in a sliding manner, guide pillar one end is fixed on the fixed block, the other end is worn to establish in the movable block, the spring both ends respectively with fixed block and movable block fixed connection, the cutter is fixed on the movable block and the cutting edge corresponds in the front side.

Further description of the utility model: the supporting component comprises a first connecting plate, a first Z-axis cylinder and a supporting table, the first connecting plate is fixed on the lower side of the first mounting plate, the first Z-axis cylinder is fixed on the first connecting plate, the power output end of the first Z-axis cylinder faces upwards, the supporting table is fixed on the power output end of the first Z-axis cylinder, and the supporting table is of an inverted T shape.

Further description of the utility model: y axle drive assembly includes the Y axle motor, the protecting crust, first slide, spacing inductor and response sheetmetal, the protecting crust is fixed on first mounting panel, the Y axle motor is fixed on first mounting panel and power take off end corresponds in the protecting crust, first slide and protecting crust top sliding connection, first slide is connected with the power take off end drive of Y axle motor, spacing inductor sets up three groups and fixes on the protecting crust along the fore-and-aft direction, the response sheetmetal is fixed on first slide and is corresponded between two sets of spacing inductors of front side, the second mounting panel is fixed on first slide.

Further description of the utility model: the pressing assembly comprises a third connecting plate, a third Z-axis cylinder, a buffering component, a connecting block and a test probe, the third connecting plate is fixed on the upper side of the first mounting plate, the third Z-axis cylinder is fixed on the third connecting plate, the power output end of the third Z-axis cylinder faces downwards, the buffering component is fixed at the power output end of the third Z-axis cylinder, the connecting block is fixed below the buffering component, the connecting block is T-shaped, and the test probe is fixed below the connecting block.

The utility model has the beneficial effects that: this design links to each other with test equipment when using, supporting component supports battery tab bottom, then move forward through Y axle drive assembly drive top banding cutting assembly, second Z axle cylinder drive cutter part is downward after that, accomplish the cutting to battery top banding both sides and carry out the conduction test, after the conduction test is qualified, then the test probe that pushes down on the subassembly moves downwards and battery tab upper end contact, accomplish the limit voltage test immediately, conduction test and the limit voltage test to the battery can be accomplished automatically to this design, and the production efficiency is improved.

Drawings

FIG. 1 is an overall block diagram of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at position A;

FIG. 3 is a block diagram of the support assembly of the present invention;

FIG. 4 is a block diagram of the Y-axis drive assembly of the present invention;

FIG. 5 is a block diagram of the hold-down assembly of the present invention;

description of reference numerals:

1. adjusting the base; 2. a first mounting plate; 3. a support assembly; 31. a first connecting plate; 32. a first Z-axis cylinder; 33. a support table; 4. a Y-axis drive assembly; 41. a Y-axis motor; 42. a protective shell;

43. a first slide plate; 44. a limit sensor; 45. an induction metal sheet; 5. a top seal edge cutting assembly;

51. a second mounting plate; 52. a second Z-axis cylinder; 53. a second slide plate; 54. an X-axis track plate;

55. a cutter member; 551. a second connecting plate; 552. a sliding table; 553. a fixed block; 554. a movable block; 555. a guide post; 556. a spring; 557. a cutter; 6. pressing the assembly; 61. a third connecting plate; 62. a third Z-axis cylinder; 63. a buffer member; 64. connecting blocks; 65. and (6) testing the probe.

Detailed Description

The utility model is further described below with reference to the accompanying drawings:

as shown in fig. 1 to 5, a battery edge voltage testing mechanism, including adjusting the base 1, first mounting panel 2, supporting component 3, Y axle drive assembly 4, top banding cutting assembly 5 and push down subassembly 6, first mounting panel 2 is vertical to be fixed on adjusting base 1, supporting component 3 installs at first mounting panel 2 downside, a utmost point ear for supporting on the battery, push down subassembly 6 and install at first mounting panel 2 upside, a utmost point ear for compressing tightly down on the battery, Y axle drive assembly 4 fixes on first mounting panel 2, top banding cutting assembly 5 installs the power take off at Y axle drive assembly 4, Y axle drive assembly 4 and top banding cutting assembly 5 respectively set up two sets ofly, the symmetry sets up the left and right sides at first mounting panel 2 respectively.

The battery is transported to the upper part of the supporting component 3 through the previous working procedure, the supporting component 3 supports the bottom of a battery tab, then the top edge sealing and cutting component 5 is driven to move forwards through the Y-axis driving component 4, then the second Z-axis cylinder 52 drives the cutter component 55 to move downwards, the cutting of the two sides of the battery top edge sealing and the conduction test are completed, and after the conduction test is qualified, the pressing component 6 moves downwards to be in contact with the upper end of the battery tab, and then the side voltage test is completed.

The top seal edge cutting assembly 5 comprises a second mounting plate 51, a second Z-axis cylinder 52, a second sliding plate 53, an X-axis track plate 54 and a cutter component 55, the second mounting plate 51 is fixed at the power output end of the Y-axis driving assembly 4, the Y-axis driving assembly 4 drives the second mounting plate 51 to move back and forth, the second Z-axis cylinder 52 is fixed on the second mounting plate 51, the second sliding plate 53 is fixed at the power output end of the second Z-axis cylinder 52 and is in sliding connection with the second mounting plate 51, the X-axis track plate 54 is fixed on the second sliding plate 53, and the cutter component 55 is fixed on the X-axis track plate 54 and is adjustable in position along the left-right direction.

The Y-axis driving component 4 drives the second mounting plate 51 to move back and forth, so that the cutter components 55 are driven to approach and cut the battery top seal edges, then the second Z-axis cylinder 52 drives the second sliding plate 53 to move downwards, the cutter components 55 are guaranteed to finish cutting the battery top seal edges, the positions of the cutter components 55 on the X-axis track plate 54 in the left and right directions are adjustable, and the distance between the two groups of cutter components 55 can be adjusted according to the sizes of different batteries.

The cutter component 55 comprises a second connecting plate 551, a sliding table 552, a fixed block 553, a movable block 554, a guide post 555, a spring 556 and a cutter 557, the second connecting plate 551 is fixed on the X-axis track plate 54 and is adjustable in position along the left-right direction, the sliding table 552 is fixed on the second connecting plate 551, the fixed block 553 is fixed on the rear side of the sliding table 552, the movable block 554 is connected with the front side of the sliding table 552 in a sliding manner, one end of the guide post 555 is fixed on the fixed block 553, the other end of the guide post 555 is arranged in the movable block 554 in a penetrating manner, two ends of the spring 556 are respectively fixedly connected with the fixed block 553 and the movable block 554, and the cutter 557 is fixed on the movable block 554 and the cutter edge corresponds to the front side.

When the Y-axis driving assembly 4 drives the cutter component 55 to approach the battery, the cutter 557 contacts the top seal edge of the battery and reaches a certain pressure, the spring 556 is compressed, meanwhile, the movable block 554 moves relatively to one side of the fixed block 553 along the guide post 555, and the movable block 554 slides on the sliding table 552, so that the cutter 557 plays a role in buffering when cutting the top seal edge of the battery, and the battery body is prevented from being damaged.

The supporting component 3 comprises a first connecting plate 31, a first Z-axis cylinder 32 and a supporting platform 33, the first connecting plate 31 is fixed on the lower side of the first mounting plate 2, the first Z-axis cylinder 32 is fixed on the first connecting plate 31, the power output end of the first Z-axis cylinder 32 faces upwards, the supporting platform 33 is fixed on the power output end of the first Z-axis cylinder 32, and the supporting platform 33 is of an inverted T shape.

The battery is transported to the top of supporting component 3 through the prior art, and first Z axle cylinder 32 drive supporting bench 33 rises, supports battery tab bottom, and supporting bench 33 is the type of falling T, makes supporting bench 33 lower extreme can firmly fix in the power take off end of first Z axle cylinder 32, and the upper end can reduce the space that occupies as far as possible, vacates the space for cutter part 55's operation.

Y axle drive assembly 4 includes Y axle motor 41, protective housing 42, first slide 43, spacing inductor 44 and response sheetmetal 45, protective housing 42 is fixed on first mounting panel 2, Y axle motor 41 is fixed on first mounting panel 2 and power take off corresponds in protective housing 42, first slide 43 and protective housing 42 top sliding connection, first slide 43 is connected with Y axle motor 41's power take off drive, spacing inductor 44 sets up three groups and fixes on protective housing 42 along the fore-and-aft direction, response sheetmetal 45 is fixed on first slide 43 and is corresponded between two sets of spacing inductors 44 in the front side, second mounting panel 51 is fixed on first slide 43.

The Y-axis motor 41 drives the first sliding plate 43 to move back and forth, so as to drive the top-sealing edge cutting assembly 5 to move back and forth, three sets of limit sensors 44 are arranged, and can be matched with the metal sheets, so that the two sets of limit sensors 44 in front can check the forward position and the backward position of the first sliding plate 43, the rearmost set of limit sensors 44 can detect the maximum backward position of the first sliding plate 43, and when the first sliding plate 43 is moved back to the maximum backward position due to a fault, the equipment is automatically stopped.

The downward pressing assembly 6 comprises a third connecting plate 61, a third Z-axis cylinder 62, a buffer component 63, a connecting block 64 and a test probe 65, the third connecting plate 61 is fixed on the upper side of the first mounting plate 2, the third Z-axis cylinder 62 is fixed on the third connecting plate 61, the power output end of the third Z-axis cylinder is downward, the buffer component 63 is fixed on the power output end of the third Z-axis cylinder 62, the connecting block 64 is fixed below the buffer component 63, the connecting block 64 is T-shaped, and the test probe 65 is fixed below the connecting block 64.

After the conduction test is carried out on the top sealing edge of the battery, the third Z-axis cylinder 62 drives the buffer component 63, the connecting block 64 and the test probe 65 run downwards, the test probe 65 contacts the battery tab downwards, so that the edge voltage test is carried out later, the buffer component 63 can play a role in buffering when the test probe 65 contacts the battery tab, the battery tab is prevented from being crushed, the connecting block 64 is T-shaped, the upper end of the connecting block 64 can be firmly fixed on the buffer component 63, the lower end can reduce occupied space as much as possible, and space is vacated for the running of the cutter component 55.

The working principle of the embodiment is as follows:

the battery is transported to the upper part of the supporting component 3 through the previous working procedure, the supporting component 3 supports the bottom of the battery tab, then the top edge sealing and cutting component 5 is driven to move forwards through the Y-axis driving component 4, then the second Z-axis cylinder 52 drives the cutter component 55 to move downwards, the cutting of the two sides of the battery top edge sealing and the conduction test are completed, after the conduction test is qualified, the test probe 65 on the pressing component 6 moves downwards to contact with the upper end of the battery tab, and then the side voltage test is completed.

The technical scope of the present invention is not limited to the above embodiments, and any modifications, equivalent variations and modifications made to the above embodiments according to the technical spirit of the present invention still fall within the technical scope of the present invention.

Claims (5)

1. The utility model provides a battery limit voltage accredited testing organization which characterized in that: the device comprises an adjusting base, a first mounting plate, a supporting assembly, a Y-axis driving assembly, a top sealing edge cutting assembly and a pressing assembly, wherein the first mounting plate is vertically fixed on the adjusting base, the supporting assembly is mounted on the lower side of the first mounting plate and used for supporting a lug on a battery, the pressing assembly is mounted on the upper side of the first mounting plate and used for pressing the lug on the battery downwards, the Y-axis driving assembly is fixed on the first mounting plate, the top sealing edge cutting assembly is mounted on a power output end of the Y-axis driving assembly, and the Y-axis driving assembly and the top sealing edge cutting assembly are respectively provided with two groups and are respectively symmetrically arranged on the left side and the right side of the first mounting plate;

the top sealing edge cutting assembly comprises a second mounting plate, a second Z-axis cylinder, a second sliding plate, an X-axis track plate and a cutter component, the second mounting plate is fixed at the power output end of the Y-axis driving assembly, the Y-axis driving assembly drives the second mounting plate to run front and back, the second Z-axis cylinder is fixed on the second mounting plate, the second sliding plate is fixed at the power output end of the second Z-axis cylinder and connected with the second mounting plate in a sliding manner, the X-axis track plate is fixed on the second sliding plate, and the cutter component is fixed on the X-axis track plate and can adjust the position along the left direction and the right direction.

2. The battery side voltage testing mechanism of claim 1, wherein: the cutter part includes second connecting plate, slip table, fixed block, movable block, guide pillar, spring and cutter, the second connecting plate is fixed on the X axle track board and along controlling the direction position adjustable, the slip table is fixed on the second connecting plate, the fixed block is fixed the rear side of slip table, the movable block with the front side sliding connection of slip table, guide pillar one end is fixed on the fixed block, the other end is worn to establish in the movable block, the spring both ends respectively with the fixed block with movable block fixed connection, the cutter is fixed on the movable block and the cutting edge corresponds in the front side.

3. The battery side voltage testing mechanism of claim 1, wherein: the supporting component comprises a first connecting plate, a first Z-axis cylinder and a supporting table, the first connecting plate is fixed to the lower side of the first mounting plate, the first Z-axis cylinder is fixed to the first connecting plate, the power output end of the first Z-axis cylinder faces upwards, the supporting table is fixed to the power output end of the first Z-axis cylinder, and the supporting table is of an inverted T shape.

4. The battery side voltage testing mechanism of claim 1, wherein: y axle drive assembly includes Y axle motor, protecting crust, first slide, spacing inductor and response sheetmetal, the protecting crust is fixed on the first mounting panel, Y axle motor fixes on the first mounting panel and power take off end corresponds in the protecting crust, first slide with protecting crust top sliding connection, first slide with the power take off end drive of Y axle motor is connected, spacing inductor sets up three groups and fixes along the fore-and-aft direction on the protecting crust, the response sheetmetal is fixed just it is two sets of in the front side to correspond on the first slide between the spacing inductor, the second mounting panel is fixed on the first slide.

5. The battery side voltage testing mechanism of claim 1, wherein: the lower pressing assembly comprises a third connecting plate, a third Z-axis cylinder, a buffering component, a connecting block and a test probe, the third connecting plate is fixed to the upper side of the first mounting plate, the third Z-axis cylinder is fixed to the third connecting plate, the power output end of the third Z-axis cylinder faces downwards, the buffering component is fixed to the power output end of the third Z-axis cylinder, the connecting block is fixed to the lower portion of the buffering component, the connecting block is T-shaped, and the test probe is fixed to the lower portion of the connecting block.

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