CN216802100U - Electricity core welding set - Google Patents

Abstract

The utility model relates to the technical field of power battery production, in particular to a battery cell welding device. The battery cell welding device mainly comprises a first platform, a second platform and a welding assembly. Wherein, be provided with the storage tank on the first platform, the storage tank is configured to place electric core. The second platform is provided with a first connecting seat, the first connecting seat is connected to the first platform, the second platform is located below the first platform along the third direction, an avoiding portion is formed in the second platform, and the first platform can rotate around the first connecting seat. The welding assembly is arranged on the second platform along the first direction, so that the welding assembly can weld the CCS assembly on the pole of the battery cell. This electric core welding set simple structure can realize simultaneously to the CCS subassembly welding on electric core utmost point post and to the welding to electric core bottom plate, simplifies the welding step process, reduces the welding degree of difficulty, and then improves welded work efficiency, practices thrift the cost.

Description

Electricity core welding set

Technical Field

The utility model relates to the technical field of power battery production, in particular to a battery cell welding device.

Background

With the rise and development of new energy, the power battery manufacturing industry will also develop rapidly, and the bottleneck of capacity and quality control is urgently needed to be broken through in power battery manufacturing. In the production process of the power battery, a processing procedure needs to weld a CCS (bus bar) assembly on the pole, so that the current in the battery core is led out conveniently. There is one process in addition to need with bottom plate or water-cooling plate welding in the bottom of electric core module to play the protection and the cooling radiating action to electric core module.

Most of the electric core welding sets in prior art are through manual welding, weld the CCS subassembly on each electric core promptly, not only waste time and energy, cause the problem of overwelding or rosin joint moreover easily. When the welding bottom plate, need the operation personnel to bend over and weld to the bottom of electricity core module, increase the welding degree of difficulty, also injure the operation personnel very easily simultaneously.

Therefore, it is desirable to design a cell welding apparatus to solve the technical problems in the prior art.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a cell welding device which is simple in structure, can simultaneously realize the welding of a CCS assembly on a cell pole and the welding of a bottom plate at the bottom of a cell, simplifies the welding step procedure, reduces the welding difficulty, further improves the welding working efficiency and saves the cost.

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

the utility model provides a battery core welding device, which comprises:

the battery cell positioning device comprises a first platform, wherein a containing groove is formed in the first platform, and the containing groove is configured to be used for containing a battery cell;

the second platform is provided with a first connecting seat, the first connecting seat is connected to the first platform, and the second platform is positioned below the first platform along a third direction;

an avoidance part is arranged on the second platform, and the first platform can rotate around the first connecting seat;

and the welding assembly is arranged on the second platform along a first direction, so that the welding assembly can weld the CCS assembly on the pole of the battery core.

As an optional technical solution, the welding assembly includes a welding hole and a laser welding gun head, and the laser welding gun can partially extend into the welding hole and weld the CCS assembly on the pole of the battery cell.

As an optional technical scheme, the welding assembly comprises a starting switch, the starting switch corresponds to the welding holes one by one, and the starting switch is connected to the laser welding gun head through a hose.

As an optional technical solution, a second connecting seat is arranged on the second platform, a rail a is arranged on the second connecting seat, and the welding assembly is slidably connected to the rail a, so that the welding assembly can move along a third direction.

As an optional technical solution, the cell welding device includes a screw, and the screw is in threaded connection with the welding assembly.

As an optional technical scheme, a handle or a motor is arranged at one end, far away from the welding assembly, of the screw rod.

As an optional technical solution, the battery cell welding device further includes a connecting shaft, and the connecting shaft is rotatably connected between the first connecting seat and the first platform.

As an optional technical solution, a stopper is further disposed on the second platform, the stopper has an upper surface and a lower surface, and when the first platform rotates to a first preset angle, the upper surface of the stopper abuts against the first platform; when the first platform rotates to a second preset angle, the lower surface of the stop block abuts against the first platform.

As an optional technical solution, the cell welding device includes a third fixing member, a rail b is disposed on the second platform, and the stopper is slidably connected to the rail b;

the stop block is provided with a first round hole, the track b is provided with a second round hole, and the third fixing part penetrates through the first round hole and is connected to the second round hole.

As an optional technical solution, the battery cell welding device further includes an AGV and a bracket, the bracket is connected to the second platform, and along the third direction, the AGV is disposed below the bracket, and the AGV is configured to move the bracket.

The utility model has the beneficial effects that:

the utility model provides a battery cell welding device which mainly comprises a first platform, a second platform and a welding assembly. Wherein, be provided with the storage tank on the first platform, the storage tank is configured to place electric core. The second platform is provided with a first connecting seat, the first connecting seat is connected to the first platform, the second platform is located below the first platform along the third direction, the avoidance portion is arranged on the second platform, and the first platform can rotate around the first connecting seat. The welding assembly is arranged on the second platform along the first direction, so that the welding assembly can weld the CCS assembly on the pole of the battery core. Through the rotation of first platform for the second platform to make the operation personnel not only can be with CCS subassembly welding on utmost point post, also can make the bottom of electric core expose in operation personnel's the field of vision simultaneously, be favorable to the operation personnel with bottom plate or liquid cooling board welding in the bottom of electric core, improve this electric core welding set's nimble suitability, and then improve welding efficiency, practice thrift the cost.

Drawings

Fig. 1 is a schematic diagram of an assembly structure of a cell stacking mechanism, a cell welding device, a bracket, and an AVG provided in an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a cell stacking mechanism and a cell welding device provided in an embodiment of the present invention;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is an enlarged view of a portion of FIG. 2 at B;

FIG. 5 is an enlarged view of a portion of FIG. 2 at C;

FIG. 6 is an enlarged view of a portion of FIG. 2 at D;

fig. 7 is a schematic structural diagram of a stopper provided in an embodiment of the present invention.

Reference numerals

100. A first platform; 110. a containing groove; 120. a first slide rail; 121. a second through hole; 130. a second slide rail; 131. a fourth via hole; 200. a second platform; 210. an avoidance part; 220. a first connecting seat; 230. a second connecting seat; 240. a connecting shaft;

1. a pressurizing device; 11. a first fixed block; 12. a first slider; 13. a screw rod; 14. a first fixing member; 15. a pressure sensor;

2. an adjustment device; 21. a second fixed block; 22. a second slider; 23. an elbow clip; 231. rotating the rod; 232. a connecting rod; 233. a push rod; 24. a second fixing member;

3. welding the assembly; 31. welding the hole; 32. starting a switch; 33. a screw;

4. a stopper; 41. an upper surface; 42. a lower surface; 43. a third fixing member; 44. a first circular hole; 45. a second circular hole;

5. AGV; 6. and (4) a bracket.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Where the terms "first position" and "second position" are two different positions, and where a first feature is "over", "above" and "on" a second feature, it is intended that the first feature is directly over and obliquely above the second feature, or simply means that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

As shown in fig. 1-2, the present embodiment provides a cell stacking mechanism, which mainly includes a first platform 100, a pressurizing device 1 and an adjusting device 2. The first platform 100 is provided with a receiving groove 110, and the receiving groove 110 is configured to receive a battery cell. In this embodiment, a plurality of electric cores are placed in the accommodating groove 110, and a connection glue layer is provided between two adjacent electric cores.

The first platform 100 is provided with a pressurizing device 1 and an adjusting device 2, the pressurizing device 1 and the adjusting device 2 are arranged oppositely, and the pressurizing device 1 and the adjusting device 2 are arranged on two sides of the battery cell. The pressurizing device 1 and the adjusting device 2 are both capable of moving on the first platform 100 along a first direction (i.e., the X-axis direction in fig. 1), so that the pressurizing device 1 can pressurize and stack the cells, that is, under the cooperative cooperation of the pressurizing device 1 and the adjusting device 2, the connecting glue layer between two adjacent cells can stably connect two adjacent cells, thereby forming a battery module, and improving the stability and reliability of the battery module.

Specifically, in the present embodiment, the weight of the first platform 100 can be reduced by the arrangement of the accommodating groove 110, and consumables and cost are saved. The pressurizing device 1 can apply a certain thrust or pressure to one side of the battery cell, and the adjusting device 2 can move along the first direction, so that the size of the accommodating groove 110 is changed, the battery cell stacking mechanism provided by the embodiment of the utility model can be suitable for pressurizing and stacking different numbers of battery cells, and the flexible applicability of the battery cell stacking mechanism is further improved. Besides, the adjusting device 2 can also play a certain blocking role on the battery cell, so that the pressurizing device 1 can not move along the first direction when pressurizing and stacking the battery cell, the battery cell in the storage tank 110 can not move along the first direction, the stacking effect of the battery cell is further improved, and the working efficiency of the battery cell stacking mechanism is improved. Pressure device 1 and adjusting device 2 set up respectively in the both sides of electric core, and pressure device 1 and adjusting device 2 are just to setting up, and then are favorable to piling up the in-process of electric core at pressure device 1 pressurization for electric core atress is even, avoids stress concentration to lead to electric core to take place the danger of rotation or displacement, thereby improves electric core stacking mechanism's stability and reliability.

Preferably, as shown in fig. 1-2, in the present embodiment, in the second direction (i.e., the Y-axis direction in fig. 1), support members are disposed on both sides of the receiving groove 110, a moving block is disposed on the support members, and a positioning block is disposed on the first platform 100, and the support members are slidably connected to the positioning block on the first platform 100 through the moving block. And then the motion through movable block and locating piece can follow the volume size that Y axle direction changed storage tank 110, and then makes storage tank 110 can be applicable to not equidimension, the electric core of different models to improve electric core stacking mechanism's universality.

Furthermore, a round hole is formed in the moving block, a plurality of positioning holes are formed in the positioning block, the round hole can be selectively connected with the positioning holes in a corresponding mode, and an operator can detachably connect the moving block and the positioning block by using bolts, screws or rivets and the like, so that the connection stability of the support piece and the first platform 100 is improved, and the situation that the support piece is rocked or displaced when the pressurizing device 1 pressurizes and stacks the battery cell is avoided.

As shown in fig. 1-2, in the present embodiment, a first slide rail 120 and a second slide rail 130 are disposed on the first platform 100, and the pressing device 1 is slidably connected to the first slide rail 120, so that the pressing device 1 can move along a first direction. The adjusting device 2 is slidably connected to the second slide rail 130, so that the adjusting device 2 can move along the first direction. The arrangement of the first slide rail 120 and the second slide rail 130 can improve the smoothness and flexibility of the movement of the pressurizing device 1 and the adjusting device 2, and avoid the working efficiency of the operator from being affected by the jamming of the pressurizing device 1 and the adjusting device 2 in the movement process.

As shown in fig. 2-3, in the present embodiment, the pressing device 1 includes a first fixed block 11, a first sliding block 12, and a screw rod 13, one end of the screw rod 13 is connected to the first fixed block 11 through a screw, and the other end is fixedly connected to the first sliding block 12, and the screw rod 13 can drive the first sliding block 12 to move along a first direction during the rotation process. Be provided with the external screw thread on the lead screw 13, set up threaded hole on the first fixed block 11, threaded hole inside is provided with the internal thread, and the operation personnel can realize the motion of lead screw 13 along the first direction through rotating lead screw 13 like this, and then makes lead screw 13 drive first sliding block 12 along the motion of first direction to make first sliding block 12 can pressurize and pile up electric core. When the battery core is pressurized and stacked, the operator can rotate the screw rod 13 in the opposite direction, so that the screw rod 13 drives the first sliding block 12 to be away from the battery core, and the stacking process of the battery core is completed.

Further, in order to improve the movement fluency of first sliding block 12, in this embodiment, a third sliding rail is further disposed on first fixed block 11, and first sliding block 12 is slidably connected to first fixed block 11 through the third sliding rail. Be provided with pressure sensor 15 on first sliding block 12, pressure sensor 15 is connected with first sliding block 12, and then makes pressure sensor 15 can real-time detection pressure value on first sliding block 12, avoids pressure device 1 the problem of excessive pressure or under-voltage to improve the product yield that the electric core piled up.

Further, a handle or a motor is disposed at an end of screw 13 away from first sliding block 12, which can be beneficial to improving convenience and flexibility of rotating screw 13. That is to say, the cell stacking mechanism in this embodiment has two functions, namely, a manual stacking mode and an automatic stacking mode. For example, when the cell stacking mechanism in this embodiment needs to be manually driven, the operator can hold the handle to shake, and then drive the lead screw 13 to drive the first sliding block 12 to approach and pressurize the cell, and the operator can observe the value of the pressure sensor 15 to ensure whether to continue shaking the handle. When electric core stacking mechanism in this embodiment needs automatic drive, the operating personnel can be through the duty cycle who sets up the motor, motor drive lead screw 13 rotates motor stop work after the certain time promptly, and then avoid pressure device 1 to appear excessive pressure or under-voltage's problem, the motor can drive lead screw 13 and drive first sliding block 12 and be close to and pressurize the electric core, after the completion is piled up in the pressurization, the motor reversal, and then drive lead screw 13 and first sliding block 12 and keep away from electric core, make the operating personnel can take out and pile up fashioned electric core.

With reference to fig. 2-3, in the present embodiment, the pressing device 1 includes a first fixing member 14, the first fixing block 11 has a first through hole, the first slide rail 120 has a second through hole 121, and the first fixing member 14 can partially pass through the first through hole and is connected to the second through hole 121. The first fixing member 14 can be a screw bolt, a screw, a bolt, or a rivet, and connects the first fixing block 11 and the first platform 100. It is worth noting that a plurality of second through holes 121 are provided in the embodiment, and the first through holes on the first fixing block 11 are selectively matched with the second through holes 121 according to the types and sizes of the battery cells, so as to improve the universality of the pressurizing device 1.

As shown in fig. 2 and 4, in the present embodiment, the adjusting device 2 includes a second sliding block 22, a second fixed block 21 and an elbow clip 23, one end of the elbow clip 23 is fixed on the second fixed block 21, and the other end of the elbow clip 23 selectively abuts against the second sliding block 22, so that the elbow clip 23 can drive the second sliding block 22 to move along the first direction when extending or retracting. Like this when the operating personnel need remove adjusting device 2, only need loosen the elbow and press from both sides 23 and can realize the elbow and press from both sides 23 and the butt of second sliding block 22, and then make second sliding block 22 can form certain clearance with electric core, be favorable to getting to put electric core or place the end plate in clearance department and be connected in order to satisfy the joint of end plate and electric core.

Further, as shown in fig. 2 and 4, in the present embodiment, the toggle clamp 23 includes a rotating rod 231, a connecting rod 232 and a pushing rod 233, one end of the connecting rod 232 is connected to the rotating rod 231, the other end is connected to the pushing rod 233, and one end of the pushing rod 233 far away from the rotating rod 231 selectively abuts against the second sliding block 22. The connecting rod 232 in this embodiment has an arc structure, which is beneficial for the connecting rod 232 to drive the push rod 233 to move along the first direction. Exemplarily, when the operating personnel orientation kept away from the direction rotation rotary rod 231 of electric core, the connecting piece drives push rod 233 and keeps away from electric core, makes like this to form certain gap between second sliding block 22 and the electric core, and then is favorable to getting to put electric core or places the end plate in clearance department and be connected in order to satisfy the joint of end plate and electric core. After the end plate is placed, the operating personnel rotates rotary rod 231 towards the direction that is close to electric core, and the connecting piece drives push rod 233 this moment to make push rod 233 drive second sliding block 22 be close to and butt end plate, thereby make second sliding block 22 can play certain supporting role to electric core and end plate, and then avoid pressure device 1 to pile up the in-process in the pressurization, and electric core takes place the displacement or deflects.

Furthermore, the second sliding block 22 is provided with a groove, and the push rod 233 is partially embedded in the groove, so that in the process that the push rod 233 drives the second sliding block 22 to move, the push rod 233 and the second sliding block 22 are not separated, and the reliability and stability of the connection between the second sliding block 22 and the push rod 233 are improved.

With reference to fig. 2 and 4, in the present embodiment, the adjusting device 2 includes a second fixing member 24, the second fixing block 21 has a third through hole, the second slide rail 130 has a fourth through hole 131, and the second fixing member 24 can partially pass through the third through hole and is connected to the fourth through hole 131. The second fixing member 24 can be a screw bolt, a screw, a bolt, or a rivet, and is used to connect the second fixing block 21 and the first platform 100. It is worth noting that a plurality of fourth through holes 131 are provided in the embodiment, and the third through holes on the second fixing block 21 are selectively matched with the fourth through holes 131 according to the type and size of the battery cell, so as to improve the universality of the adjusting device 2.

Further, in order to improve the movement fluency of the second sliding block 22, in this embodiment, a fourth sliding rail is further disposed on the second fixed block 21, and the second sliding block 22 is slidably connected to the second fixed block 21 through the fourth sliding rail.

Furthermore, in this embodiment, a limiting portion is disposed at an end of the second slide rail 130 away from the electric core, and the limiting portion can limit the second fixing block 21 in the adjustment device 2, so as to prevent the second fixing block 21 from slipping off the second slide rail 130, and further improve stability and reliability of the adjustment device 2.

As shown in fig. 1-2 and 5, the present embodiment provides a battery cell welding apparatus, which mainly includes a first platform 100, a second platform 200 and a welding assembly 3, wherein a receiving groove 110 is disposed on the first platform 100, and the receiving groove 110 is configured to receive a battery cell. The second platform 200 is provided with a first connecting seat 220, the first connecting seat 220 is connected to the first platform 100, the second platform 200 is located below the first platform 100 along a third direction (i.e., a Z-axis direction in fig. 1), the second platform 200 is provided with an avoiding portion 210, and the first platform 100 can rotate around the first connecting seat 220. The welding assembly 3 is disposed on the second platform 200 along the first direction, so that the welding assembly 3 can weld the CCS assembly on the pole of the battery cell. It should be noted that the first platform 100 of the cell welding device and the first platform 100 of the cell stacking mechanism are the same component, that is, the cell stacking mechanism and the cell welding device share the first platform 100.

Specifically, when electric core stacking mechanism piles up a plurality of electric cores pressurization and becomes electric core module, the operation personnel can place the CCS subassembly on the utmost point post position of electric core, and then make welding subassembly 3 on the electric core welding set can weld the CCS subassembly on the utmost point post of electric core. The avoidance part 210 is formed in the second platform 200, and the first platform 100 can rotate around the first connecting seat 220, so that the welding assembly 3 can weld the CCS assembly on the opposite side of the battery cell and can also weld the bottom plate on the bottom of the battery cell, and the flexible applicability of the battery cell welding device is improved.

As shown in fig. 2 and 5, in the present embodiment, the welding assembly 3 includes a welding hole 31 and a laser welding gun head, and the laser welding gun can partially extend into the welding hole 31 and weld the CCS assembly on the pole of the battery cell. In this embodiment, welding hole 31 sets up to a plurality ofly, and the laser welding rifle head selectively stretches into welding hole 31, that is to say, when the laser welding rifle head need weld the CCS subassembly on a certain electric core utmost point post, the laser welding rifle head can stretch into the welding hole 31 nearest apart from this CCS subassembly, and then accomplishes welding work, and then the laser welding rifle head withdraws from this welding hole 31, gets into next welding hole 31 and continues the welding to this analogizes and accomplishes the welding work of the CCS subassembly on all electric core utmost point posts.

Further, the welding assembly 3 includes starting switch 32, and starting switch 32 and welding hole 31 one-to-one, and starting switch 32 passes through the hose connection in the laser welding rifle head, that is to say, starting switch 32 also sets up to a plurality ofly in this embodiment, and the hose can make the nimble removal of laser welding rifle head, and then is favorable to the laser welding rifle head to stretch into different welding holes 31 and weld.

Preferably, in this embodiment, the number of the welding assemblies 3 is two, and the two welding assemblies 3 are symmetrically arranged on two sides of the battery core along the second direction, so that the welding assemblies 3 can weld two sides of the battery core at the same time, the welding efficiency is improved, and the welding process of the CCS assembly can also be ensured. And the cell is stressed uniformly along the second direction.

As shown in fig. 2, in the present embodiment, the second platform 200 is provided with a second connecting seat 230, the second connecting seat 230 is provided with a track a, and the welding assembly 3 is slidably connected to the track a, so that the welding assembly 3 can move along a third direction, i.e. along the Z-axis direction.

Specifically, set up two second connecting seats 230 at the both ends of every welding set 3 symmetrically, make welding set 3 carry out direction of height's removal through track a like this, and then realize changing the height for second platform 200 of welding set 3 to change the high position in welding hole 31, the CCS subassembly of the different high positions of laser welding rifle head welding of being convenient for improves this electric core welding set's application scope.

Further, the battery core welding device comprises a screw 33, the screw 33 is in threaded connection with the welding assembly 3, and a handle or a motor is arranged at one end, away from the welding assembly 3, of the screw 33. That is, the welding module 3 in the present embodiment is provided with both the manual mode and the automatic mode. For example, when welding subassembly 3 in this embodiment needs manual drive, the operation personnel can hand the handle and wave, and then drive screw 33 and drive welding subassembly 3 and be close to the utmost point post of electric core, and the operation personnel is through observing the distance of screw hole apart from the utmost point post of electric core, and then ensure whether continue to wave the handle. When welding subassembly 3 in this embodiment needs automatic drive, the operation personnel can be through the duty cycle who sets up the motor, and motor drive screw 33 rotates motor stop work after the certain time promptly, and then avoids welding subassembly 3 to collide the utmost point post of electric core, and the motor can drive screw 33 and drive welding subassembly 3 and be close to the utmost point post of electric core, and then the laser welding rifle head of being convenient for stretches into welding hole 31 and welds the CCS subassembly. After welding of welding set 3 is accomplished, the motor reverses, and then drives screw rod 33, and screw rod 33 drives welding set 3 and keeps away from electric core for the operation personnel can take out and have accomplished CCS subassembly welded electric core module.

As shown in fig. 2, in the present embodiment, the cell welding apparatus further includes a connecting shaft 240, and the connecting shaft 240 is rotatably connected between the first connecting seat 220 and the first platform 100. Preferably, the present embodiment provides two connecting shafts 240 and two connecting seats, and the connecting shafts 240 are rotatably connected to the connecting seats along the X-axis direction. A handle or a motor is arranged at the end of one of the connecting shafts 240, so that the connecting shaft 240 can be driven to rotate manually or the connecting shaft 240 can be driven to rotate automatically by the motor. The straight line where the axes of the two connecting shafts 240 are located coincides with the straight line where the axis of the first platform 100 is located, so that the first platform 100 is stressed more uniformly, and the phenomenon that the first platform 100 shakes or is unstable when rotating is avoided.

As shown in fig. 6-7, in the present embodiment, the second platform 200 is further provided with a stopper 4, the stopper 4 has an upper surface 41 and a lower surface 42, and when the first platform 100 rotates to a first preset angle, the upper surface 41 of the stopper 4 abuts against the first platform 100; when the first platform 100 rotates to a second predetermined angle, the lower surface 42 of the stopper 4 abuts against the first platform 100.

Illustratively, two stoppers 4 are provided in the present embodiment, and the two stoppers 4 are disposed in a central symmetry with respect to the second platform 200, that is, the two stoppers 4 are disposed on a diagonal line of the second platform 200, which is beneficial to distribute the gravity of the first platform 100, so that the first platform 100 is stressed more uniformly. Of course, in other embodiments of the present invention, the operator may also set 4 blocks 4, that is, 4 blocks 4 are distributed at four angular positions of the first platform 100 to support and fix the first platform 100, which is not limited in this embodiment.

Further, the cell welding device includes a third fixing member 43, a rail b is disposed on the second platform 200, and the stopper 4 is slidably connected to the rail b; the stopper 4 has a first circular hole 44, the rail b has a second circular hole 45, and the third fixing member 43 partially passes through the first circular hole 44 and is connected to the second circular hole 45. When the first preset angle is 0 degrees, that is, the position of the first platform 100 in fig. 1, the upper surface 41 of the stopper 4 abuts against the lower surface 42 of the first platform 100, so that the first platform 100 is in a stable state, which is beneficial for welding the CCS assembly on the pole of the battery cell by the laser welding gun head; after CCS subassembly welding finishes, the operation personnel can be dismantled third mounting 43, then withdraw from dog 4 along track b, then rotate first platform 100 to the second and predetermine the angle, be about to first platform 100 upset 180 degrees, later impel dog 4 along track b, make dog 4 can the butt in the upper surface 41 of first platform 100, thereby make the bottom of electric core expose in operation personnel's the field of vision, and then be favorable to the operation personnel to weld bottom plate or liquid cooling board in the bottom of electric core, improve this electric core welding set's nimble suitability, and then improve welding efficiency, and save cost.

As shown in fig. 1, in the present embodiment, the cell welding apparatus further includes an AGV5(Automated Guided Vehicle) and a rack 6, the rack 6 is connected to the second platform 200, the AGV5 is disposed below the rack 6 in the third direction, and the AGV5 is configured to move the rack 6. AGV5 can drive support 6 and remove with arbitrary direction, and support 6 drives second platform 200 and first platform 100 and removes, and then realizes that AGV5 can drive electric core stacking mechanism and electric core welding set and carry out nimble removal to the demand of different technology sections when satisfying the operation of actual mill.

Further, the bottom of support 6 is provided with four gyro wheels, like this when AGV5 transports support 6 to the purpose, AGV5 can withdraw from support 6's below, and the gyro wheel contacts with ground this moment, and then makes the operation personnel can adjust first platform 100 and second platform 200 to suitable position in a flexible way to battery cell stack mechanism and battery cell welding set stack and weld the pressurization to battery cell.

The specific working principle is as follows:

(1) and (3) stacking: the operation personnel place a plurality of electric cores, connection glue film and end plate in storage tank 110, make second sliding block 22 can the butt on the end plate through adjusting second fixed block 21 on adjusting device 2, then press from both sides the rotary rod 231 on 23 through the elbow that rotates for connecting rod 232 can drive push rod 233 and compress tightly the end plate, has just so realized adjusting device 2 coarse adjusting and the fine setting effect to electric core. Then can remove first fixed block 11 on the pressure device 1 through the operation personnel for first fixed block 11 is close to electric core and reaches suitable position, later rotate through drive lead screw 13, and then make lead screw 13 can drive first sliding block 12 and carry out and follow the first direction and remove, first sliding block 12 can be close to and pressurize like this and pile up electric core, the operation personnel can be through observing pressure sensor 15's numerical value, and then ensure whether electric core accomplishes the process that the pressurization piles up, that is to say can guarantee that electric core can not appear excessive pressure or the risk of undervoltage.

(2) And (3) welding: the operation personnel can place the CCS subassembly between electric core utmost point post and welding subassembly 3, then through drive screw 33, make welding subassembly 3 can carry out the removal along the third direction through track a on the second connecting seat 230, and then realize changing the height for second platform 200 of welding subassembly 3, thereby change the high position of welding hole 31, just when the utmost point post of electric core is just being gone up in the position of welding hole 31, the operation personnel open starting switch 32, make the laser welding rifle head can stretch into welding hole 31 and weld under the drive of hose.

(3) And (3) turning: after welding set 3 welds the CCS subassembly on the utmost point post of electric core, the operation personnel can rotate through drive connecting axle 240, detach third mounting 43 through the operation personnel this moment, then withdraw from dog 4 along track b, then predetermine the angle with first platform 100 rotation to the second, be about to first platform 100 upset 180 degrees, later impel dog 4 along track b, make dog 4 can the butt in the upper surface 41 of first platform 100, thereby make the bottom of electric core expose in operation personnel's the field of vision, and then be favorable to the operation personnel to weld bottom plate or liquid cooling plate in the bottom of electric core, improve this electric core welding set's nimble suitability, and then improve welding efficiency, and save cost.

(4) The transfer process comprises: when electric core stacking mechanism and electric core welding set in this embodiment need remove and carry, the operation personnel can be through controlling AGV5 for AGV5 can drive support 6 and remove with arbitrary direction, and support 6 drives second platform 200 and first platform 100 and removes, and then realizes that AGV5 can drive electric core stacking mechanism and electric core welding set and remove in a flexible way, thereby the demand of different technology sections when satisfying the operation of actual mill.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. A cell welding device, comprising:

the battery cell support platform comprises a first platform (100), wherein a containing groove (110) is formed in the first platform (100), and the containing groove (110) is configured to contain a battery cell;

a second platform (200), wherein a first connecting seat (220) is arranged on the second platform (200), the first connecting seat (220) is connected to the first platform (100), and the second platform (200) is positioned below the first platform (100) along a third direction;

an avoidance part (210) is arranged on the second platform (200), and the first platform (100) can rotate around the first connecting seat (220);

the welding assembly (3) is arranged on the second platform (200) along a first direction, so that the welding assembly (3) can weld a CCS assembly on a pole of the battery cell.

2. The cell welding device according to claim 1, wherein the welding assembly (3) comprises a welding hole (31) and a laser welding gun head, and the laser welding gun head can partially extend into the welding hole (31) and weld the CCS assembly on the pole of the cell.

3. The battery cell welding device according to claim 2, wherein the welding assembly (3) comprises a starting switch (32), the starting switch (32) corresponds to the welding holes (31) in a one-to-one manner, and the starting switch (32) is connected to the laser welding gun head through a hose.

4. The cell welding device according to claim 2, wherein a second connecting seat (230) is arranged on the second platform (200), a track a is arranged on the second connecting seat (230), and the welding assembly (3) is slidably connected to the track a so that the welding assembly (3) can move along a third direction.

5. The cell welding device according to claim 2, characterized in that it comprises a screw (33), the screw (33) being screwed to the welding assembly (3).

6. The cell welding device according to claim 5, characterized in that a handle or a motor is arranged at one end of the screw (33) away from the welding assembly (3).

7. The cell welding device according to claim 1, further comprising a connection shaft (240), wherein the connection shaft (240) is rotatably connected between the first connection seat (220) and the first platform (100).

8. The cell welding device according to claim 7, wherein a stopper (4) is further disposed on the second platform (200), the stopper (4) having an upper surface (41) and a lower surface (42), and when the first platform (100) rotates to a first preset angle, the upper surface (41) of the stopper (4) abuts against the first platform (100); when the first platform (100) rotates to a second preset angle, the lower surface (42) of the stop block (4) abuts against the first platform (100).

9. The battery cell welding device according to claim 8, characterized in that the battery cell welding device comprises a third fixing member (43), a track b is arranged on the second platform (200), and the stop block (4) is slidably connected to the track b;

the stop block (4) is provided with a first round hole (44), the track b is provided with a second round hole (45), and the third fixing piece (43) partially penetrates through the first round hole (44) and is connected with the second round hole (45).

10. Cell welding device according to any of claims 1-9, further comprising an AGV (5) and a carriage (6), the carriage (6) being connected to the second platform (200), the AGV (5) being arranged below the carriage (6) in the third direction, the AGV (5) being configured to move the carriage (6).

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