CN220627876U - V-shaped adhesive sticking device for battery - Google Patents

Abstract

The utility model relates to a V-shaped adhesive sticking device for a battery. The utility model relates to a V-shaped adhesive sticking device for a battery, which comprises the following components: the device comprises a support frame, an X-axis driving assembly, a Z-axis driving assembly and a rubberizing mechanism, wherein the support frame comprises a beam and a stand column, and the stand column supports the beam; the X-axis driving assembly drives the first mounting plate to move along the X axis on the cross beam, and the Z-axis driving assembly on the first mounting plate drives the second mounting plate to move along the Z axis; the rubberizing mechanism is arranged on the second mounting plate and is used for rubberizing the lugs of the battery cells; the rubberizing mechanism comprises a tongue inserting assembly and a sucking disc assembly, and the tongue inserting assembly and the sucking disc assembly are matched to paste the V-shaped adhesive. The V-shaped adhesive sticking device for the battery has the advantage of high production efficiency.

Description

V-shaped adhesive sticking device for battery

Technical Field

The utility model relates to a battery cell rubberizing device, in particular to a battery rubberizing V-shaped rubberizing device.

Background

In the traditional battery cell manufacturing process, the tab needs to be rubberized after the battery cell is welded, so that the tab is insulated and protected, and in the traditional rubberizing mode, a V-shaped groove is extruded at the joint of the rubberized tab and the battery cell through the inserting tongue, so that the joint of the tab is extended, and the rubberized tab is not easy to tear.

However, since the tab becomes more fragile after tab welding, the tongue is inserted downwards to insert the V-shaped groove when pasting the V-shaped adhesive, and the risk of tearing easily occurs when the adhesive tape is compressed in the adhesive tape pasting process is also present, the tongue is required to be matched with the adhesive tape pressing component to operate, and the action speed is reduced, so that the adhesive tape pasting action is more gentle, and therefore, the conventional adhesive tape pasting mode has the defects of complex integrated action, long action time and low production efficiency.

Disclosure of Invention

Therefore, the utility model aims to provide the V-shaped adhesive sticking device for the battery, which is characterized in that the V-shaped adhesive is firstly stuck at the joint of the tabs through the adhesive sticking mechanism before welding, so that the tearing of the tabs is avoided, then the V-shaped adhesive is stuck without matching the adhesive pressing component with the inserting tongue after the welding of the tabs is finished, the adhesive sticking step is reduced, the action time is short, and the V-shaped adhesive sticking device has the advantage of high production efficiency.

The utility model is realized by the following scheme:

the battery paste V-shaped glue device comprises a support frame, wherein the support frame comprises a cross beam and a stand column, the stand column supports the cross beam, and one end of the cross beam extends to the upper part of a battery cell transmission line;

the X-axis driving assembly comprises a first guide rail and an X-axis driving unit, the first guide rail is arranged on the side surface of the cross beam along the X-axis, and the X-axis driving unit is used for driving a first mounting plate which is slidably arranged on the first guide rail;

the Z-axis driving assembly comprises a second guide rail and a Z-axis driving unit, the second guide rail is arranged on the first mounting plate along the Z-axis, and the Z-axis driving unit is used for driving the second mounting plate which is slidably arranged on the second guide rail;

the rubberizing mechanism is arranged on the second mounting plate and is used for rubberizing the lugs of the battery cells; the rubberizing mechanism comprises a tongue inserting assembly and a sucking disc assembly, and the tongue inserting assembly and the sucking disc assembly are matched to achieve the purpose of rubberizing the V-shaped adhesive.

Further, the sucking disc subassembly includes first sucking disc, second sucking disc, first sucking disc drive unit and second sucking disc drive unit, first sucking disc drive unit with second sucking disc drive unit with the second mounting panel is connected, and the drive direction along Z axle setting, first sucking disc drive unit's output with first sucking disc is connected, second sucking disc drive unit's output with the second sucking disc is connected, first sucking disc with the suction hole of second sucking disc is down.

Further, the insert tongue assembly comprises an insert tongue and a connecting plate, wherein the insert tongue is arranged between the first sucker and the second sucker along the Z-axis direction, and the insert tongue is fixedly connected with the second mounting plate through the connecting plate.

Further, the first sucker, the inserting tongue and the second sucker are sequentially arranged from the electrode lug to the direction of the main body of the battery cell.

Further, a third mounting plate is arranged below the cross beam at one side of the battery cell transmission line, and an adhesive tape unreeling assembly, a roller assembly and an adhesive pulling assembly are arranged on the third mounting plate;

the adhesive tape unreeling assembly comprises a carrier disc mounting shaft, an adhesive tape carrier disc is mounted on the carrier disc mounting shaft, and adhesive tape on the adhesive tape carrier disc is led out and then is transmitted to the adhesive pulling assembly through the roller assembly.

Further, the roller assembly comprises a first transition roller, a second transition roller, a tensioning wheel, a third guide rail and a tensioning wheel driving unit, wherein the first transition roller and the second transition roller are arranged on the same horizontal line, the third guide rail is arranged along the perpendicular bisector of the first transition roller and the second transition roller, the tensioning wheel is slidably arranged on the third guide rail, and the tensioning wheel driving unit drives the tensioning wheel to move on the third guide rail.

Further, the glue pulling assembly comprises a first glue clamping block, a second glue clamping block, a first sliding groove, a first glue clamping driving unit and a second glue clamping driving unit, wherein the first sliding groove is arranged on the third mounting plate along the Z-axis direction, the first glue clamping block is mounted on the first sliding groove through the first glue clamping driving unit, and the second glue clamping block is mounted on the first sliding groove through the second glue clamping driving unit.

Further, the glue pulling assembly further comprises a cutter, a second chute and a cutter driving unit, wherein the second chute is arranged on one side, close to the battery cell, of the first chute along the Z-axis direction, and the cutter is installed on the second chute through the cutter driving unit.

Further, a cushion block assembly is further arranged on one side, close to the battery cell transmission line, of the third mounting plate, the cushion block assembly comprises a cushion block, a fourth guide rail and a cushion block driving unit, the fourth guide rail is arranged on the third mounting plate along the X axis, the cushion block is slidably arranged on the fourth guide rail, and the cushion block driving unit drives the cushion block to move.

Further, the V-shaped adhesive sticking device comprises two adhesive sticking devices which are respectively arranged on two sides of the electric core transmission line.

The V-shaped adhesive sticking device for the battery has the following beneficial effects:

1. before welding, the V-shaped adhesive is firstly adhered to the joint of the tab by the adhesive adhering mechanism, and then welding is carried out, so that the probability of tearing the tab during welding can be reduced; after the tab welding is finished, the first rubberizing before welding is protected, the tongue insertion is directly used for fast rubberizing of the V-shaped rubber, fine operation of matching of the rubber pressing assembly is saved, rubberizing steps are simplified, action time is short, and the V-shaped rubber has the advantage of high production efficiency.

2. Through the cooperation of first sucking disc drive unit and Z axle drive unit, paste the sticky tape in electric core main part at first sucking disc back, insert tongue downward movement and insert utmost point ear junction, form a V type groove at utmost point ear junction, then the second sucking disc pastes the rubberizing of surplus portion on the utmost point ear again, make glue utmost point ear junction more ductile through the subsides of first time before the welding, insert tongue can insert fast when the rubberizing of second time, need not the cooperation of glue pressing subassembly, and reduce the probability that the utmost point ear was torn.

For a better understanding and implementation, the present utility model is described in detail below with reference to the drawings.

Drawings

Fig. 1 is a side view of a V-shaped adhesive device for battery according to an embodiment of the present utility model;

fig. 2 is a perspective view of a V-shaped adhesive device for battery according to an embodiment of the present utility model;

FIG. 3 is an enlarged view of a rubberizing mechanism of a battery rubberizing device according to an embodiment of the utility model;

fig. 4 is a perspective view of a third mounting plate of the V-shaped adhesive device for battery according to an embodiment of the present utility model.

Reference numerals: support 100, beam 110, upright 120, first mounting plate 130, second mounting plate 140, third mounting plate 150;

an X-axis driving assembly 200, a first guide rail 210, an X-axis driving unit 220;

a Z-axis driving assembly 300, a second guide rail 310, a Z-axis driving unit 320;

the adhesive sticking mechanism 400, the inserting tongue component 410, the inserting tongue 411, the connecting plate 412, the sucker component 420, the first sucker 421, the second sucker 422, the first sucker driving unit 423 and the second sucker driving unit 424;

an adhesive tape unreeling assembly 500, a carrier disc mounting shaft 510;

roller assembly 600, first transition roller 610, second transition roller 620, tensioning wheel 630, third guide 640, roller drive unit 650;

the glue pulling assembly 700, the first glue gripping block 710, the second glue gripping block 720, the first chute 730, the first glue gripping driving unit 740, the second glue gripping driving unit 750, the cutter 760, the second chute 770 and the cutter driving unit 780;

a pad assembly 800, a pad 810, a fourth rail 820, a pad driving unit 830;

cell 00.

Detailed Description

The following are specific embodiments of the present utility model and the technical solutions of the present utility model will be further described with reference to the accompanying drawings, but the present utility model is not limited to these embodiments.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

In order to solve the technical problems in the background art, the utility model provides a battery V-shaped adhesive sticking device, as shown in fig. 1, comprising a support frame 100, an X-axis driving assembly 200, a Z-axis driving assembly 300 and an adhesive sticking mechanism 400.

As shown in fig. 2, the support frame 100 includes a beam 110 and a column 120, the column 120 supporting the beam 110, one end of the beam 110 extending above the cell transmission line. The X-axis driving assembly 200 includes a first rail 210 and an X-axis driving unit 220, the first rail 210 is disposed on a side of the beam 110 along the X-axis, and the X-axis driving unit 220 is used for driving the first mounting plate 130 slidably disposed on the first rail 210. The Z-axis driving assembly 300 includes a second guide rail 310 and a Z-axis driving unit 320, the second guide rail 310 is disposed on the first mounting plate 130 along the Z-axis, and the Z-axis driving unit 320 is used for driving the second mounting plate 140 slidably disposed on the second guide rail 310.

The rubberizing mechanism 400 is arranged on the second mounting plate 140 and is used for rubberizing the lugs of the battery cell 00; the rubberizing mechanism 400 comprises a tongue inserting assembly 410 and a sucking disc assembly 420, and the tongue inserting assembly 410 and the sucking disc assembly 420 are matched to paste V-shaped adhesive.

According to the V-shaped adhesive sticking device for the battery, the first guide rail 210 is arranged on the cross beam of the support frame 100 along the X-axis direction, the first mounting plate 130 which is slidably arranged on the first guide rail 210 is driven to move along the X-axis direction by the X-axis driving unit 220, the second guide rail 310 is arranged on the first mounting plate 130 along the Z-axis, and the second mounting plate 140 which is slidably arranged on the second guide rail 310 is driven to move along the Z-axis direction by the Z-axis driving unit 320. The rubberizing mechanism 400 is arranged on the second mounting plate 140, and a mechanical arm mechanism is formed through the X-axis driving assembly 200 and the Z-axis driving assembly 300, so that the rubberizing mechanism 400 moves in the X-axis direction and the Z-axis direction to pick up the rubberizing and rubberizes the battery cells twice before and after welding.

Specifically, the rubberizing mechanism 400 is provided with a tongue inserting component 410 and a sucking disc component 420, the sucking disc component 420 sucks rubberizing before the first rubberizing before welding, and before the adhesive tape is pasted on the welding position of the tab from the battery cell main body, the tongue inserting component 410 can be inserted into a V-shaped groove at the joint of the tab during rubberizing; and in the second rubberizing after welding, the sucking disc component 420 absorbs rubberizing, and the adhesive tape is pasted from the battery cell body to the welding mark covering the tab, when rubberizing, the inserting tongue component 410 is inserted into the connecting part of the tab to form a V-shaped groove, and the inserting tongue component 410 and the sucking disc component 420 are matched to finish twice rubberizing of the V-shaped adhesive.

According to the battery V-shaped adhesive sticking device, the V-shaped adhesive is stuck at the joint of the lugs through the adhesive sticking mechanism 400 before welding, and then welding is carried out, so that the probability of tearing the lugs during welding can be reduced; after the tab welding is finished, the first rubberizing before welding is protected, the tongue insertion is directly used for fast rubberizing of the V-shaped rubber, fine operation of matching of the rubber pressing assembly is saved, rubberizing steps are simplified, action time is short, and the V-shaped rubber has the advantage of high production efficiency.

In a specific embodiment, as shown in fig. 2 and 3, the suction cup assembly 420 includes a first suction cup 421, a second suction cup 422, a first suction cup driving unit 423 and a second suction cup driving unit 424, the first suction cup driving unit 423 and the second suction cup driving unit 424 are connected with the second mounting plate 140, and the driving direction is set along the Z-axis, an output end of the first suction cup driving unit 423 is connected with the first suction cup 421, an output end of the second suction cup driving unit 424 is connected with the second suction cup 422, and suction holes of the first suction cup 421 and the second suction cup 422 face downward. The present embodiment provides a first suction cup 421 and a second suction cup 422, which are driven to move up and down in the Z-axis direction by a first suction cup driving unit 423 and a second suction cup driving unit 424, respectively. When the adhesive is adhered, the first sucker 421 and the second sucker 422 suck the adhesive, the first sucker 421 moves downwards to adhere the adhesive to the main body of the battery cell, and then the second sucker 421 also moves downwards to adhere the adhesive to the tab.

Further, as shown in fig. 3, the insert tongue assembly 410 includes an insert tongue 411 and a connecting plate 412, the insert tongue 411 is disposed between the first suction cup 421 and the second suction cup 422 along the Z-axis direction, and the insert tongue 411 is fixedly connected with the second mounting plate 140 through the connecting plate 412. The inserting tongue 411 is arranged between the first sucking disc 421 and the second sucking disc 422, when the first sucking disc 421 corresponds to the position of attaching the battery core main body and the second sucking disc 422 corresponds to the position of attaching the electrode lug, the inserting tongue 411 corresponds to the joint of the battery core main body and the electrode lug, after the adhesive tape is attached to the battery core main body by the matching of the first sucking disc driving unit 423 and the Z-axis driving unit 320, the inserting tongue 411 moves downwards to insert the electrode lug joint, a V-shaped groove is formed at the electrode lug joint, then the second sucking disc 422 attaches the adhesive tape of the rest part to the electrode lug, the adhesive tape electrode lug joint is more ductile by the first attachment before welding, the inserting tongue 411 can be inserted quickly during the second adhesive tape attachment without the matching of an adhesive pressing assembly, and the probability of electrode lug tearing is reduced.

In a specific embodiment, as shown in fig. 3, the first suction cup 421, the insertion tongue 411, and the second suction cup 422 are sequentially disposed from the tab toward the cell body. When the adhesive tape is adhered, the first sucker 421 corresponds to the position of the battery cell main body, the inserting tongue 411 corresponds to the position of the joint of the battery cell main body and the tab, and the second sucker 422 corresponds to the position of the tab, so that the arrangement positions of the first sucker 421, the inserting tongue 411 and the second sucker 422 are sequentially arranged from the tab to the direction of the battery cell main body.

In a preferred embodiment, as shown in fig. 1 and 4, a third mounting plate 150 is provided under the beam 110 at one side of the cell transmission line, and an adhesive tape unreeling assembly 500, a roller assembly 600, and an adhesive pulling assembly 700 are provided on the third mounting plate 150. The tape unreeling assembly 500 comprises a carrier disc mounting shaft 510, wherein a tape carrier disc is mounted on the carrier disc mounting shaft 510, and the tape on the tape carrier disc is led out and then is transmitted to the tape pulling assembly 700 through the roller assembly 600. By arranging the adhesive tape unreeling assembly 500, the roller assembly 600 and the adhesive tape pulling assembly 700, the adhesive tape is pulled out of the adhesive tape carrying disc, cut into corresponding lengths and then rubberized by the rubberizing mechanism 400.

In a preferred embodiment, as shown in fig. 4, the roller assembly 600 includes a first transition roller 610, a second transition roller 620, a tensioning roller 630, a third guide rail 640, and a tensioning roller driving unit 650, the first transition roller 610 and the second transition roller 620 are disposed on the same horizontal line, the third guide rail 640 is disposed along a perpendicular bisector of the first transition roller 610 and the second transition roller 620, the tensioning roller 630 is slidably disposed on the third guide rail 640, and the tensioning roller driving unit 650 drives the tensioning roller 630 to move on the third guide rail 640. After the adhesive tape is pulled out of the adhesive tape unreeling assembly 500, the adhesive tape can bypass the roller assembly 600, the tension wheel 630 is contained in the roller assembly 600, and the position of the tension wheel 630 on the third guide rail 640 is adjusted through the tension wheel driving unit 650, so that the adhesive tape with different tension can be output according to the requirement.

In a preferred embodiment, as shown in fig. 4, the adhesive pulling assembly 700 includes a first adhesive clamping block 710, a second adhesive clamping block 720, a first sliding groove 730, a first adhesive clamping driving unit 740 and a second adhesive clamping driving unit 750, wherein the first sliding groove 730 is disposed on the third mounting plate 150 along the Z-axis direction, the first adhesive clamping block 710 is mounted on the first sliding groove 730 through the first adhesive clamping driving unit 740, and the second adhesive clamping block 720 is mounted on the first sliding groove 730 through the second adhesive clamping driving unit 750. By arranging the first adhesive clamping block 710 and the second adhesive clamping block 720 to move mutually to clamp the adhesive tape when the adhesive is not taken, the adhesive is moved away from each other when the adhesive is taken, and the adhesive tape is clamped after the adhesive is taken, so that the adhesive tape is prevented from losing tension.

Further, the glue pulling assembly 700 further includes a cutter 760, a second sliding groove 770, and a cutter driving unit 780, wherein the second sliding groove 770 is disposed on one side of the first sliding groove 730, which is close to the battery cell 00, along the Z-axis direction, and the cutter 760 is mounted on the second sliding groove 770 through the cutter driving unit 780. After the removal of the adhesive is completed, the first and second adhesive clamping blocks 710 and 720 clamp the adhesive tape, and then the cutter 760 cuts the adhesive tape by the cutter driving unit, and the cut adhesive tape is absorbed by the adhesive applying mechanism 400 to apply the adhesive.

In a preferred embodiment, as shown in fig. 1 and 4, a spacer block assembly 800 is further disposed on a side of the third mounting plate 150 near the cell transmission line, the spacer block assembly 800 includes a spacer block 810, a fourth guide rail 820 and a spacer block driving unit 830, the fourth guide rail 820 is disposed on the third mounting plate 150 along the X-axis, the spacer block 810 is slidably disposed on the fourth guide rail 820, and the spacer block driving unit 830 drives the spacer block 810 to move. When the adhesive tape is adhered, the cushion block driving unit 830 drives the cushion block 810 to be inserted under the electrode lug of the battery core, and when the second sucker 422 presses the adhesive tape, the electrode lug is prevented from being directly bent to be torn, and supporting force is provided for the electrode lug.

In a specific embodiment, the V-shaped adhesive sticking device includes two adhesive sticking devices respectively disposed on two sides of the electric core transmission line. The V-shaped adhesive sticking devices are respectively arranged on the two sides of the transmission line, and the V-shaped adhesive sticking devices are respectively used for simultaneously sticking the V-shaped adhesive to the lugs on the two sides of the battery cell, so that the high-efficiency adhesive sticking is maintained.

The application is said a battery pastes V type and glues device, has following beneficial effect:

1. before welding, the V-shaped adhesive is firstly adhered to the joint of the tab by the adhesive adhering mechanism 400, and then welding is carried out, so that the probability of tearing the tab during welding can be reduced; after the tab welding is finished, the first rubberizing before welding is protected, the tongue insertion is directly used for fast rubberizing of the V-shaped rubber, fine operation of matching of the rubber pressing assembly is saved, rubberizing steps are simplified, action time is short, and the V-shaped rubber has the advantage of high production efficiency.

2. Through the cooperation of first sucking disc drive unit 423 and Z axle drive unit 320, paste the sticky tape in the electric core main part at first sucking disc 421, insert tongue 411 downward movement and insert utmost point ear junction, form a V type groove in utmost point ear junction, then second sucking disc 422 paste the rubberizing of surplus portion on utmost point ear again, paste the rubberizing extremely ear junction through the welding the first time and make more ductility, insert tongue 411 can insert fast when rubberizing the second time, need not the cooperation of glue pressing subassembly, and reduce the probability that utmost point ear was torn.

The above examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that modifications and improvements can be made by those skilled in the art without departing from the spirit of the utility model, and the utility model is intended to encompass such modifications and improvements.

Claims (10)

1. The utility model provides a V type is glued to battery pastes device which characterized in that includes:

the support frame (100), the support frame (100) comprises a cross beam (110) and a stand column (120), the stand column (120) supports the cross beam (110), and one end of the cross beam (110) extends to the upper part of the cell transmission line;

an X-axis driving assembly (200) comprising a first guide rail (210) and an X-axis driving unit (220), wherein the first guide rail (210) is arranged on the side surface of the cross beam (110) along the X-axis, and the X-axis driving unit (220) is used for driving a first mounting plate (130) which is slidably arranged on the first guide rail (210);

the Z-axis driving assembly (300) comprises a second guide rail (310) and a Z-axis driving unit (320), wherein the second guide rail (310) is arranged on the first mounting plate (130) along the Z axis, and the Z-axis driving unit (320) is used for driving a second mounting plate (140) which is slidably arranged on the second guide rail (310);

the rubberizing mechanism (400) is arranged on the second mounting plate (140) and is used for rubberizing the lugs of the battery cells (00); the rubberizing mechanism (400) comprises a tongue inserting assembly (410) and a sucking disc assembly (420), and the tongue inserting assembly (410) and the sucking disc assembly (420) are matched to achieve the purpose of rubberizing the V-shaped adhesive.

2. The battery paste V-bank adhesive apparatus of claim 1, wherein:

the sucker assembly (420) comprises a first sucker (421), a second sucker (422), a first sucker driving unit (423) and a second sucker driving unit (424), wherein the first sucker driving unit (423) and the second sucker driving unit (424) are connected with the second mounting plate (140), the driving direction is set along the Z axis, the output end of the first sucker driving unit (423) is connected with the first sucker (421), the output end of the second sucker driving unit (424) is connected with the second sucker (422), and the suction holes of the first sucker (421) and the second sucker (422) are downward.

3. The battery paste V-bank adhesive apparatus of claim 2, wherein:

the inserting tongue assembly (410) comprises an inserting tongue (411) and a connecting plate (412), the inserting tongue (411) is arranged between the first sucker (421) and the second sucker (422) along the Z-axis direction, and the inserting tongue (411) is fixedly connected with the second mounting plate (140) through the connecting plate (412).

4. The battery paste V-bank adhesive apparatus of claim 3, wherein:

the first sucker (421), the inserting tongue (411) and the second sucker (422) are sequentially arranged from the electrode lug to the direction of the main body of the battery cell.

5. The battery paste V-shaped glue apparatus according to any one of claims 1-4, wherein:

a third mounting plate (150) is arranged below the cross beam (110) at one side of the battery cell transmission line, and an adhesive tape unreeling assembly (500), a roller assembly (600) and an adhesive pulling assembly (700) are arranged on the third mounting plate (150);

the adhesive tape unreeling assembly (500) comprises a carrier disc mounting shaft (510), an adhesive tape carrier disc is mounted on the carrier disc mounting shaft (510), and adhesive tape on the adhesive tape carrier disc is led out and then is transmitted to the adhesive pulling assembly (700) through the roller assembly (600).

6. The battery paste V-bank adhesive apparatus of claim 5, wherein:

the roller assembly (600) comprises a first transition roller (610), a second transition roller (620), a tensioning wheel (630), a third guide rail (640) and a tensioning wheel driving unit (650), wherein the first transition roller (610) and the second transition roller (620) are arranged on the same horizontal line, the third guide rail (640) is arranged along the perpendicular bisector of the first transition roller (610) and the second transition roller (620), the tensioning wheel (630) is slidably arranged on the third guide rail (640), and the tensioning wheel driving unit (650) drives the tensioning wheel (630) to move on the third guide rail (640).

7. The battery paste V-bank adhesive apparatus of claim 6, wherein:

the glue pulling assembly (700) comprises a first glue clamping block (710), a second glue clamping block (720), a first sliding groove (730), a first glue clamping driving unit (740) and a second glue clamping driving unit (750), wherein the first sliding groove (730) is arranged on the third mounting plate (150) along the Z-axis direction, the first glue clamping block (710) is mounted on the first sliding groove (730) through the first glue clamping driving unit (740), and the second glue clamping block (720) is mounted on the first sliding groove (730) through the second glue clamping driving unit (750).

8. The battery paste V-bank adhesive apparatus of claim 7, wherein:

the glue pulling assembly (700) further comprises a cutter (760), a second chute (770) and a cutter driving unit (780), wherein the second chute (770) is arranged on one side, close to the battery cell (00), of the first chute (730) along the Z-axis direction, and the cutter (760) is installed on the second chute (770) through the cutter driving unit (780).

9. The battery paste V-bank adhesive apparatus of claim 8, wherein:

the battery cell transmission line is characterized in that a cushion block assembly (800) is further arranged on one side, close to the battery cell transmission line, of the third mounting plate (150), the cushion block assembly (800) comprises a cushion block (810), a fourth guide rail (820) and a cushion block driving unit (830), the fourth guide rail (820) is arranged on the third mounting plate (150) along the X axis, the cushion block (810) is slidably arranged on the fourth guide rail (820), and the cushion block driving unit (830) drives the cushion block (810) to move.

10. The battery paste V-shaped glue apparatus according to any one of claims 1-4, wherein:

the V-shaped adhesive sticking device comprises two adhesive sticking devices which are respectively arranged on two sides of the electric core transmission line.