CN213692138U - Shaping device and welding equipment before welding of electric core module - Google Patents

Abstract

The utility model discloses a pre-welding shaping device of an electric core module and welding equipment, wherein the pre-welding shaping device of the electric core module comprises a carrying platform; the battery core end plate shaping mechanism is provided with a side surface shaping mechanism, an end surface shaping mechanism and a top pressing mechanism; the side plate attaching mechanism is provided with a positioning space for placing the side plate and a structure for driving the side plate at the positioning space to be attached to the assembly on the carrying platform; the guard mechanism includes a guard having a defined aperture facing the engagement seam of the side plate and the end plate, the guard being coupled to a guard drive mechanism that drives movement of the guard at least flush with the end face of the stage. This scheme can carry out the accurate laminating of curb plate after electric core and end plate plastic to guaranteed the position precision of electric core, end plate and curb plate, be favorable to improving the product quality of welding back electricity core module, adopt protection machanism simultaneously, can avoid effectively that the welding slag splashes and avoids the damage of laser scattering to other parts.

Description

Shaping device and welding equipment before welding of electric core module

Technical Field

The utility model belongs to the technical field of battery processing equipment and specifically relates to shaping device and welding equipment before welding of electricity core module.

Background

With the rapid development of new energy automobiles, battery packs as core components of new energy automobiles are concerned by more and more enterprises.

In the production process of the battery pack, it is necessary to assemble the battery core 30, the end plate 20 and the side plate 10 as shown in fig. 1 into a whole. During the equipment, thereby overall structure's stability when needing to guarantee the position accuracy of each part when guaranteeing the welding, more excellent, before laminating electric core 30 and end plate 20 with curb plate 10 on, need carry out the plastic with electric core and end plate earlier.

In order to realize automatic assembly, corresponding automatic equipment needs to be designed to shape the battery cell and the end plate and accurately position and attach the shaped end plate.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an electricity core module welds preceding shaping device and welding equipment in order to solve the above-mentioned problem that exists among the prior art exactly.

The purpose of the utility model is realized through the following technical scheme:

shaping device before electric core module group welding for curb plate and end plate welding of electric core module, it includes

A carrier having a carrier plane;

the battery core end plate shaping mechanism is provided with a side surface shaping mechanism, an end surface shaping mechanism and a top pressing mechanism;

the side plate attaching mechanism is provided with a positioning space for placing the side plate and a structure for driving the side plate at the positioning space to be attached to the assembly of the shaped battery cell and the end plate on the loading platform;

a guard mechanism including a guard having a defined aperture facing the engagement seam of the side plate and the end plate, the guard being connected to a guard drive means which drives movement thereof into engagement with the end plate and/or the end flap of the side plate.

Preferably, the side shaping mechanism and the top pressing mechanism are located on the same transfer mechanism, and the transfer mechanism drives the side shaping mechanism and the top pressing mechanism to move synchronously between a first position and a second position, wherein the top pressing mechanism is located above the carrier at the first position, and the top pressing mechanism is located outside the carrier at the second position.

Preferably, the top pressing mechanism comprises a plurality of pressing members arranged in close proximity, each pressing member is connected with a guide shaft extending longitudinally, the guide shafts movably penetrate through and are limited on the mounting member, a spring is sleeved on the periphery of each guide shaft, one end of each spring is connected with the corresponding pressing member, the other end of each spring is connected with the mounting member, and the mounting member is connected with a lifting driving device for driving the mounting member to lift.

Preferably, the mounting part comprises a mounting beam corresponding to each pressing piece, the mounting beams are detachably arranged on the two side mounting plates, and the mounting beams are hung on the main beam.

Preferably, the side plate positioning space comprises an L-shaped supporting plate and two limiting blocks located at two ends of the L-shaped supporting plate, and each limiting block is connected with a multi-directional driving device for driving the side plate to move horizontally in a reciprocating manner along a first horizontal direction and a second horizontal direction.

Preferably, the supporting plate is arranged on a supporting plate, and a sucking disc penetrating through the supporting plate is arranged on the supporting plate.

Preferably, both ends of the supporting plate extend out of both ends of the supporting plate, and the supporting plate further comprises a side plate end pressing mechanism which comprises pressing blocks corresponding to the parts of the supporting plate extending out of the supporting plate, and each pressing block is connected with a pressing driving device which drives the pressing driving device to reciprocate along a first horizontal direction and cling to the supporting plate.

Preferably, the lifting device comprises a side plate bottom supporting mechanism which comprises pressure heads positioned outside two sides of the carrying platform, the pressure heads are arranged on bolts, the bolts are movably arranged on the support plate, and the support plate is connected with a lifting driving device for driving the support plate to lift.

Preferably, the protection member is further connected with an air pipe, and the air pipe is communicated with the limiting hole.

Welding set, including any of the aforesaid electric core module plastic device before welding.

The utility model discloses technical scheme's advantage mainly embodies:

the shaping device of this scheme carries out the plastic through setting up electric core end plate plastic mechanism to electric core and the end plate on the microscope carrier, be used for fixing a position the curb plate and carry out the curb plate laminating through setting up curb plate laminating device, can carry out the accurate laminating of curb plate after electric core and end plate plastic, thereby electric core has been guaranteed, the position precision of end plate and curb plate, be favorable to improving the product quality of welding back electricity core module, adopt protection machanism simultaneously, can avoid effectively welding the sediment to splash and avoid the damage of laser scattering to other parts, the life of extension part.

The side plastic mechanism and the top mechanism of exerting pressure of this scheme are located same and move and carry the mechanism, can conveniently carry out the material loading of electric core, end plate and curb plate and the unloading of welding back electricity core module, and it facilitates for automatic last unloading.

The mechanism is applyed at the top of this scheme adopts a plurality of independent pieces that compress tightly to can independently exert pressure in order to guarantee the validity of plastic to every electric core and end plate effectively. And, the top mechanism of exerting pressure of this scheme can compress tightly the quantity of piece according to the nimble adjustment of the quantity of electric core, uses in a flexible way.

The curb plate location space of this scheme adopts layer board and two stopper cooperations to make two stoppers portable, thereby can dodge after the curb plate location, guarantee the realization of laminating. The reliability that the both ends region and end plate and electric core laminating of curb plate can be guaranteed effectively to combination curb plate tip hold-down mechanism and curb plate bottom sprag mechanism, avoids appearing the seam and influences welded stability.

The protection piece of this scheme is connected the trachea, can carry out the collection of waste residue according to the needs of difference in order to improve welding environment and avoid welding slag pollution product, or carry out protective gas's supply in order to improve welding quality.

This scheme will be located two pressure heads, two briquetting and two protectors of same end and set up on the carriage of terminal surface plastic mechanism to follow terminal surface clamp plate synchronous motion, can adapt to the location and the laminating needs of the curb plate of different length effectively, improved the suitability.

Drawings

Fig. 1 is a schematic view of an end plate and a side plate of a cell module to be welded according to the present invention (one of the side plates is in a separated state);

fig. 2 is a perspective view of the battery cell module pre-welding shaping device of the present invention;

fig. 3 is a front view of the side shaping mechanism, the top pressing mechanism and the transferring mechanism of the present invention;

fig. 4 is a perspective view of the side shaping mechanism, the top pressing mechanism and the transferring mechanism of the present invention;

FIG. 5 is an enlarged view of area B of FIG. 4;

fig. 6 is a partial bottom view of the side shaping mechanism, the top pressing mechanism and the transferring mechanism of the present invention;

fig. 7 is a top view of the battery cell module pre-welding shaping device with the side shaping mechanism, the top pressing mechanism and the transferring mechanism hidden (the upper supporting plate and the protection member at the upper right corner are hidden in the figure);

FIG. 8 is an enlarged view of the area C in FIG. 7 (in this case, the distance between two stoppers for forming a positioning space is greater than the length of the side plate);

FIG. 9 is an end view of the side plate applying mechanism and the side plate end pressing mechanism;

fig. 10 is a partial perspective view of the pressing mechanism and the pressing head, pressing block, and protecting member on the sliding frame of the end face reshaping mechanism of the present invention (a protecting member is hidden in the drawing);

FIG. 11 is an end view of the structure of FIG. 10 (shown with a guard and carriage synchronization chain, etc. hidden);

FIG. 12 is an enlarged view of area A of FIG. 2;

fig. 13 is a front view of the welding apparatus of the present invention.

Detailed Description

Objects, advantages and features of the present invention will be illustrated and explained by the following non-limiting description of preferred embodiments. These embodiments are merely exemplary embodiments for applying the technical solutions of the present invention, and all technical solutions formed by adopting equivalent substitutions or equivalent transformations fall within the scope of the present invention.

In the description of the embodiments, it should be noted that the terms "center", "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "inner", "outer", and the like 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 devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the embodiment, the operator is used as a reference, and the direction close to the operator is a proximal end, and the direction away from the operator is a distal end.

It is right below combining the figure the utility model discloses a shaping device before welding of electricity core module explains, and it is used for the shaping before the welding of curb plate 10, end plate 20 and electric core 30 as shown in figure 1's electric core module, as shown in figure 2, it includes work base station 900, be provided with microscope carrier 100, electric core end plate plastic mechanism 200, curb plate laminating mechanism 300, protection machanism 400 on the work base station 900.

As shown in fig. 2, the carrier 100 is used for placing two end plates 20 and a plurality of tightly adhered cells 30, and includes a bearing plane 110, where the bearing plane 110 is a top surface of a rectangular block 120, the length of the bearing plane is greater than the sum of the thicknesses of all the cells 30 and the end plates, and the width of the bearing plane is smaller than the width of the cell module 30, the block 120 is disposed on a base 130, and the base 130 is fixed on the working base 900.

The cell end plate shaping mechanism 200 is used for positioning and shaping a plurality of cells 30 on the carrier 100 and two end plates 20 located at two ends of the cells, and includes a side shaping mechanism 210, an end face shaping mechanism 220, and a top pressing mechanism 230.

The side shaping mechanism 210 can apply opposite pressure to two opposite sides of the assembly formed by all the battery cells 30 and the end plates 10, so as to realize the side shaping and positioning of the assembly, and the side shaping mechanism 210 can be of various known feasible structures. As shown in fig. 3 and 4, the two side pressing mechanisms are located on two sides of the carrier 100, and the two side pressing mechanisms have the same structure, but may also have different structures.

As shown in fig. 3 and 4, the side pressing mechanism includes a side pressing plate 211 vertically disposed, the side pressure plates 211 are connected to an adapter plate 212, the adapter plate 212 is connected to a driving cylinder 213 for driving the adapter plate 212 to reciprocate along the second horizontal direction Y, guide shafts 214 positioned at both sides of the driving cylinder 213 are fixed to the adapter plate 212, the guide shaft 214 is movably inserted into the base plate 215, the driving cylinder 213 is also fixed to the base plate 215, said base plate 215 is slidably arranged on rails 216 extending in the longitudinal direction Z, said rails 216 being fixed to a fixed frame 217, the base plate 215 is connected to a lifting drive cylinder 218 which drives the base plate to slide back and forth along the guide rail 216, the lifting driving cylinder 218 is fixed on the fixing frame 217, and an avoiding hole (not shown in the figure) for the guiding shaft 214 to reciprocate along the longitudinal direction Z is formed on the fixing frame 217.

As shown in fig. 3, the top pressing mechanism 230 is used for applying pressure from the tops of all the battery cells 30 and the end plates 10, the top pressing mechanism 230 is located between the two side pressing mechanisms, and the top pressing mechanism 230 may be any feasible pressing mechanism, such as a pressing member 231, and the pressing member 231 is connected to drive the pressing member 231 to move up and down and press down a driving cylinder. However, in this structure, the pressing member is usually in hard contact with the top of the battery cell and the top of the end plate, which has a certain influence on the safety of the battery cell, so in a more preferred structure, the pressing member 231 may also be connected to the pressing driving cylinder by an elastic structure, thereby achieving a soft contact between the pressing member and the top of the battery cell and the top of the end plate.

The pressing member 231 may be a member capable of contacting top portions of all the battery cells and the terminals, and in a more preferred mode, as shown in fig. 4 and 5, the top pressing mechanism 230 includes a plurality of pressing members 231 arranged next to each other, each pressing member 231 faces the top of one of the end plates 20 or one of the battery cells 30, and ends of two pressing members facing two end plates 20 at two ends are lower than ends of the pressing members facing the battery cells, so as to ensure that the pressing members facing the end plates 20 can effectively contact the top portions of the end plates 20 when the pressing members corresponding to the battery cells 30 contact the top portions of the battery cells.

As shown in fig. 5 and fig. 6, each of the pressing members 231 includes a floating frame 2312 having a width corresponding to the width of the battery cell, and a pressing roller 2311 protruding out of the bottom of the floating frame 2312 is rotatably disposed at the bottom of the floating frame 2312, wherein two pressing rollers 2311 having a same axis and a same gap are disposed on the floating frame 2312 of each of the pressing members 231 facing each of the battery cells 30, and the two pressing rollers 2311 correspond to the electrode positions of the battery cells respectively. A press roller having a width smaller than the length of the end plate is provided on the floating frame 2312 of the pressing member 231 corresponding to each of the end plates 20.

Furthermore, as shown in fig. 3 and 5, the floating frame 2312 of each pressing member 231 is connected with a guide shaft 232 extending along the longitudinal direction Z, the guide shaft 232 movably passes through and is limited on a mounting member 233, that is, the guide shaft 232 is movably suspended on the mounting member 233, the outer periphery of the guide shaft 232 is sleeved with a spring 234, one end of the spring 234 is connected (abutted against or fixed) to the top of the pressing member 231, the other end of the spring 234 is connected (abutted against or fixed) to the bottom of the mounting member 233, the mounting member 233 is connected with a lifting driving device 235 for driving the lifting driving device to lift, the lifting driving device 235 can be various devices capable of generating linear movement, such as an air cylinder, an electric push rod, an hydraulic cylinder, etc., the lifting driving device 235 is fixed on a carrier plate (not shown in the figure), the mounting member 233 is further connected with a guide column 236 extending along the longitudinal direction, the guide posts 236 are movably inserted into the carrier plate.

Further, in order to adjust the number of the pressing members 231 to accommodate different numbers of battery cells, as shown in fig. 5, the mounting member 233 includes two side mounting plates 2331 which are spaced and parallel, a row of connecting holes 2332 are respectively formed on the two side mounting plates 2331, the connecting holes are arranged in a row, the positions of which are corresponding to each other, and the number of the mounting beams 2333 is equal to the number of the pressing members 231, each mounting beam 2333 is fixed on the side mounting plate 2331 by bolts (not shown) connected to a pair of coaxial connecting holes 2332, a trapezoidal limiting through-slot 2334 is formed on the top surface of each mounting beam 2333, a group of the mounting beams 2333 is suspended on a main beam 2335 which is perpendicular to the mounting beams 2333, and the main beam 2335 has a plug-in part that conforms to the shape of the restricted through-slot 2334, while the mounting beam 2333 is threaded with the main beam 2335. The main beam 2335 is fixed to a main plate 2336, the main plate 2336 is connected to a driving unit of the lifting driving device 235, and the main plate 2336 is guided by a guide shaft and a sleeve.

As shown in fig. 3 and attached body 4, the side pressure plates 211 of the side shaping mechanism 210 have a height range that allows the side pressure plates to descend below the pressing member 231 and ascend above the bottom of the pressing member 231.

In a more preferred embodiment, in order to facilitate loading and unloading of the battery cell 30, the end plate 20, and the side plate 10, as shown in fig. 3 and fig. 4, the side shaping mechanism 210 and the top pressing mechanism 230 are located on the same transfer mechanism 240, the transfer mechanism 240 drives the side shaping mechanism 210 and the top pressing mechanism 230 to move between a first position and a second position synchronously, and at the first position, the top pressing mechanism 230 is located above the carrier 100, so that the battery cell and the end plate can be shaped; in the second position, the top application mechanism 220 is located outside the carrier 100 to provide space for loading and unloading.

Specifically, as shown in fig. 3, the transfer mechanism 240 includes a bracket 241, the carrier plate on which the lifting/lowering driving device 235 is located, the fixing frames 217 of the two side pressing mechanisms, and the lifting/lowering driving cylinder 218 are all disposed on the bracket 241, the bracket 241 is movably disposed on two side frames 242, and the side frames 242 are disposed on the work base 900 and located on two sides of the long side of the stage 100. The carriage 241 is connected to a transfer driving device 243 for driving the carriage to reciprocate in the first horizontal direction X, and the transfer driving device 243 may be any of various known devices capable of generating linear movement, such as an air cylinder, a linear motor, and the like, and preferably may be a slide cylinder or an electric cylinder including a motor and a screw. Of course, in another embodiment, the bracket 241 may be disposed on other moving mechanisms, for example, the bracket 241 is disposed on a four-axis robot or a six-axis robot.

As shown in fig. 7, the end face shaping mechanism 220 is configured to apply opposite pressures to two ends of an assembly of the battery cell and the end plate on the carrier 100, so as to position and shape the assembly, and the end face shaping mechanism 220 includes a baffle 221 located at one end of the carrier 100, where the baffle 221 is directly opposite to the carrier 100 and is vertically disposed above the carrier plane 110, and the baffle 221 is fixed on the work base 900 through a support 222.

As shown in fig. 7, the end face shaping mechanism 220 further includes a pressing mechanism 223 at the other end of the carrier 100, the pressing mechanism 223 includes an end surface pressing plate 2231, the end surface pressing plate 2231 is perpendicular to the supporting plane 110 and is higher than the supporting plane 110, the end surface press plate 2231 is fixed on two side support plates 2232, the distance between the two side support plates 2232 is larger than the width of the support plane 110, the two side support plates 2232 are fixed on a sliding frame 2233, the carriage 2233 is reciprocally movable in a first horizontal direction X on the top surface of the work base 900, the sliding frame 2233 is connected to a stitching driving device 2234 for driving the sliding frame to move back and forth, the stitching driving device 2234 may be a device capable of moving linearly, such as an air cylinder, an electric push rod, etc., in addition, in a more preferred embodiment, the pressing driving device 2234 employs a device capable of stepless adjusting the conveying distance, such as a rodless cylinder, an electric push rod, and the like.

The side plate 10 can be attached after the shaping of the battery cell and the end plate is completed, and the side plate attaching mechanism 300 is used for placing and positioning the side plate 10 and attaching the side plate 10 to the side surface of the assembly formed by the shaped battery cell and the end plate.

Specifically, as shown in fig. 7 and 8, the side plate attaching mechanism 300 includes two positioning spaces 310 located at two sides of the carrier 100 and used for placing and positioning the side plates 10, and an attaching driving device 320 for driving the side plates 10 located at the positioning spaces 310 to attach, where the positioning spaces 310 are formed by an L-shaped supporting plate 311 and two limiting blocks 313 symmetrically located at two ends of the supporting plate 311.

As shown in fig. 7 and 8, the supporting plate 311 faces the carrier 100 and has a length corresponding to the sum of the thicknesses of all the battery cells, and the top surface of the bottom plate 3111 is slightly lower than the supporting plane 110 so that the bottom plate portion of the side plate 10 thereon can smoothly move to the bottoms of the battery cell module and the end plate. Meanwhile, the width of the bottom plate 3111 of the supporting plate 311 is greater than the width of the bottom plate portion 11 of the side plate 10, so that the side plate 10 is prevented from falling from the supporting plate 311 during movement.

As shown in fig. 8, the stopper 313 includes a stopper plane 3131 parallel to the vertical stopper surface 3112 of the supporting plate 311 and an end stopper surface 3132 perpendicular to the stopper plane 3131, and when the two stoppers 313 and the supporting plate 311 form the positioning space, the stopper plane 3131 is located on the upper side of the vertical stopper surface 3113, and the distance between the end stopper surfaces 3132 of the two stoppers 313 is equal to the length of the side plate, so that the position of the side plate can be effectively positioned to ensure that the end flap 13 of the side plate 10 can correspond to the outer end surface positions of the two end plates.

In addition, when the side plates 10 are attached, because the two limit blocks 313 shield the two ends of the side plates, therefore, the stoppers 313 at both ends need to be moved to the outer sides of both ends of the side plate 10 before attaching, if, however, it is moved only to the outside of the side panel 10, then subsequent weld positioning and masking will interfere, correspondingly, as shown in fig. 9, each of the stoppers 313 is connected with a multi-directional driving device 314 for driving the stopper to reciprocate horizontally along a first horizontal direction X and a second horizontal direction Y perpendicular to each other, the multi-directional drive 314 is preferably implemented using two cylinders, one large cylinder 3141, one small cylinder 3142, that is, the large cylinder 3141 is fixed to the foot rest on the work base 900, and the cylinder axis thereof extends in the second horizontal direction Y, and the small cylinder 3142 is fixed to the cylinder axis of the large cylinder and the cylinder axis thereof reciprocates in the first horizontal direction X.

The two limit blocks 313 are moved to the outer sides of the two ends of the side plate 10, so that the side plate can be attached, and correspondingly, the supporting plate 313 needs to be capable of moving towards the direction of the stage 100, specifically, as shown in fig. 8, the supporting plate 313 is connected to an attachment driving device 320 for driving the supporting plate 313 to reciprocate along the second horizontal direction Y, and the attachment driving device 320 may be a known device such as an air cylinder, an electric push rod, or a hydraulic cylinder capable of generating linear movement.

In a more preferred embodiment, as shown in fig. 8, the supporting plate 311 is disposed on a supporting plate 312 shorter than the supporting plate, and two ends of the supporting plate extend out of two ends of the supporting plate 312, and the supporting plate 312 can effectively provide a supporting force for the supporting plate 311 during fitting, so as to ensure the fitting degree. Meanwhile, in order to ensure that the side plate 10 is kept stable and does not shift on the supporting plate 311, in a preferred embodiment, as shown in fig. 9, a suction cup 315 is disposed on the supporting plate 312 and penetrates through the supporting plate 311, and the suction cup 315 can generate a certain suction force to the side plate to keep the side plate stable during the movement. Of course, in another embodiment, the suction cup 315 may be replaced by a vacuum suction nozzle, or when the side plate is a magnetic object, the supporting plate 311 or the supporting plate 312 is made of a magnetic material such as a magnet.

Since the length of the whole side plate 10 is relatively long, if a long support plate 311 is used, the length of the corresponding support plate 312 is also long, and at this time, the support force provided by the support plate 311 to the two end regions of the side plate is often insufficient, so that, as shown in fig. 8, a support plate shorter than the length of the support plate is used to sufficiently support the main body portion of the riser of the support plate 311, and at the same time, another mechanism is used to provide support to the two end regions of the riser.

Specifically, as shown in fig. 7, 8 and 10, the pre-welding shaping device for electric core module further includes a side plate end pressing mechanism 600, which includes a plurality of pressing blocks 610, preferably four pressing blocks 610, located above the supporting plane 100, where each pressing block 610 has a length corresponding to a width of a vertical plate of the pallet, and four pressing blocks 610 respectively opposite to four portions of the vertical plates of the two pallets 311 extending out of the supporting plate 320, each pressing block 610 is located outside an end surface of the corresponding pallet 311 facing away from the stage 100 (two pressing blocks on the upper side are located on the upper side of the pallet 311 on the upper side, and two pressing blocks on the lower side are located on the lower side of the pallet on the lower side), each pressing block 610 is connected to a pressing driving device 620 for driving the corresponding pallet 311 to reciprocate along the second horizontal direction Y, and the pressing driving device 620 may be a known cylinder capable of generating linear movement, or a cylinder, Electric push rod, hydraulic cylinder and the like, and the pressing driving device 620 is fixed on the foot rest where the multi-directional driving device 314 is located and is located above the large cylinder.

Meanwhile, since the length of the supporting plate 311 is adjusted according to the length of the side plate 10 in actual use, in a more preferable embodiment, as shown in fig. 8, the positions of the two pressing drive devices 621 located at one end (left end) of the stage 100 are fixed, and the two pressing drive devices 622 located at the other end of the stage 100 are made to be capable of reciprocating in the first horizontal direction X, and in a more preferable embodiment, as shown in fig. 11, the two pressing drive devices 622 located at the other end of the stage 100 are provided on the carriage 2233 of the end surface shaping mechanism 220 to be capable of reciprocating in the first horizontal direction while following the carriage 2233.

Further, since the supporting force of the bottom plate 3111 of the supporting plate 311 to the side plate is relatively weak, as shown in fig. 7, the welding apparatus further includes a side plate bottom supporting mechanism 700, where the side plate bottom supporting mechanism 700 includes pressing heads 710 located outside two sides of the stage, and the number of the pressing heads 710 is preferably 4, and two pressing heads 710 are used for pressing two end regions of the bottom plate portion 31 of one side plate. Moreover, as shown in fig. 7, the horizontal installation positions of two pressing heads 710 (two pressing heads on the left side) close to the baffle 221 are fixed, and as shown in fig. 11, the other two pressing heads 710 (two pressing heads on the right side) are located on the sliding frame 2233 of the pressing mechanism 223 and located at the front end (left side) of the end plate 2231, so that the end region fitting requirements of the bottom plate portions 11 of the side plates with different lengths can be effectively met.

As shown in fig. 10 and 11, each of the pressing heads 710 is disposed on a resilient mechanism, which may be a spring, in a preferred embodiment, the resilient mechanism includes a bolt 720, the pressing head 710 is fixed on the top of the bolt 720, the bolt 720 is disposed on a carrier plate 730 capable of moving back and forth along the longitudinal direction Z, a spring 740 is disposed on the top surface of the carrier plate 730 and the tail portion of the bolt 720, the carrier plate 730 is connected to drive the lifting and lowering thereof, and the lifting driving device 750 may be any known device capable of generating linear movement. In order to save the jacking driving device 750, two bolts 720 of the pressing head 710 at the same end of the stage 100 are located on one carrier plate 730.

Welding operation can be carried out after the attachment of the side plate is completed, before welding, the joint seam of the supporting plate and the side plate needs to be positioned through the protection mechanism 400, and meanwhile welding slag splashing and damage to other parts caused by laser scattering are prevented. As shown in fig. 11 and 12, the guard mechanism 400 includes guard members 410, each of the guard members 410 is a rectangular parallelepiped, and each of the guard members 410 has a limiting hole 420, and four limiting holes 420 are respectively aligned with one of four engaging seams of end flanges of two side plates 10 and outer end surfaces of two end plates. Therefore, during welding, the welding head can be opposite to the limiting hole 420, welding slag during welding can be blocked in the limiting hole 420, and splashing is not easy to occur.

As shown in fig. 11, each of the protection components 410 is connected to a protection component driving device 440 for driving the protection component 410 to reciprocate along the first horizontal direction X and to be attached to an end surface of the assembly on the carrier 100, and the protection component driving device 440 may be any known device capable of generating a linear movement, which is not described herein again.

In order to accommodate side plates of different lengths, if the guard driving devices 440 corresponding to the four guards 410 are fixed in position, the side plates 10 of only one length may be accommodated, and in a more preferred embodiment, as shown in fig. 7 and 11, the guard driving devices 440 corresponding to the two guards 410 on the left side are fixed in position and located on both sides of the supporting member 222, and the guard driving devices 440 corresponding to the two guards 410 on the right side are disposed on the sliding frame 2233 of the end face shaping mechanism 220.

Further, as shown in fig. 12, the protecting part 410 is further connected with an air pipe 430, the air pipe 430 is communicated with the limiting hole 420, the air pipe 430 comprises a connecting bucket 431, the large open end of the connecting bucket 431 is connected with the protecting part 410, the small open end of the connecting bucket 431 is connected with one end of a pipeline 432, and the other end of the pipeline 432 can be connected with a dust suction device (not shown in the figure), so that welding slag can be collected during welding; of course, the other end of the pipe 432 may be connected to a shielding gas supply line so as to supply shielding gas to the welding position for shielding during welding.

Welding can be performed after the positioning and the protection of the welding seam are completed, and correspondingly, the present disclosure also discloses a welding apparatus, which includes the above shaping device before welding, as shown in fig. 13, the welding device 500 beside the working base 900, the welding device 500 includes a laser welding device 510 and a moving mechanism 520 for driving the laser welding device 510 to move, the specific structures of the laser welding device 510 and the moving mechanism 520 are known technologies, which are not the innovation point of the present disclosure, and are not described herein again, in this embodiment, the moving mechanism 520 takes a multi-axis moving robot as an example, and can drive the welding head of the laser welding device 510 to face the limited hole.

The specific process of welding the end plate 20 and the side plate 10 by the welding device is described in detail below, and the welding method comprises the following steps:

in a normal state, the side shaping mechanism 210 and the top shaping mechanism 230 are located outside the carrier 100, the end surface pressing plate 2231 is kept away from the end of the carrier 100, the stop block 313 is located at the end of the supporting plate 311, that is, the cylinder axis of the large cylinder extends out, and the cylinder axis of the small cylinder retracts.

S1, a combination of a set of battery cells 30 and two end plates 20 is placed on the carrier 100 and side plates are placed on the pallet manually or by automated equipment.

S2, the pressing driving device 2234 of the end face shaping mechanism 320 starts to drive the end face pressing plate 2231 to move toward the carrier 100, so as to clamp the electrical core and the end plate between the baffle 221 and the end face pressing plate to achieve end face shaping, and meanwhile, the two pressing blocks 610 on the sliding frame 2233 move to the right end regions of the corresponding supporting plates and close to the right end of the supporting plate 312. Both pressing heads 710 on the sliding rack 2233 move to the bottom of the cell and close to the right end of the carrier 100. The stopper 313 on the sliding frame 2233 is moved to the right end of the pallet and positioned with the stopper 313 at the other end of the pallet to position the side panel 10.

S3, the transferring mechanism 240 drives the side shaping mechanism 210 and the top shaping mechanism 230 to move to the positions above the battery cells 30 and the end plate 20 on the carrier 100. Subsequently, the lifting/lowering driving cylinders 218 of the side shaping mechanism 210 drive the two substrates 215 to move down so that the two side pressing plates 211 move to both sides of the combined body on the stage 100, and then the two driving cylinders 213 drive the two side pressing plates 211 to apply pressure to both sides of the combined body for shaping, and after shaping is completed, the combined body is reset.

S4, the lifting driving device 235 of the top pressing mechanism 230 drives the pressing member 231 to move downward and apply pressure to the top of each of the battery cells and the end plates for holding.

S5, after shaping the electric core and the end plate, extending the cylinder shafts of the small cylinders of the four multi-directional driving devices 312 to move each of the position-limiting blocks 313 in the first horizontal direction X toward the end away from the supporting plate 311, then retracting the cylinder shafts of the four large cylinders to drive the four position-limiting blocks 313 to move in the second horizontal direction Y and away from the carrier 100, until the four position-limiting blocks 313 move to the outer side of the corresponding supporting plate 312, which faces away from the end surface of the carrier 100.

S6, the two bonding driving devices 320 drive the two carrier plates 311 to move in the direction of the assembly on the stage 100 until the two side plates 10 on the carrier plates 311 are bonded to the assembly.

S7, the four pressing driving devices 620 of the side plate end pressing mechanism 600 drive the four pressing blocks 610 to move toward the carrier 100, so that the four pressing blocks 610 apply pressure to the areas where the two supporting plates extend out of the two ends of the supporting plate 312.

S8, the four lifting driving devices 740 of the side plate bottom supporting mechanism 700 drive the four pressing heads 710 to ascend and apply pressure to the two end regions of the bottom plate portions of the two side plates.

S9, the four stopper driving devices 440 of the protection mechanism 400 drive the four protection members 410 to move toward the carrier 100 respectively until the four protection members 410 are respectively attached to the end flaps of the end plates and/or the side plates.

And S10, finally, the moving mechanism 520 drives the welding head of the laser welding device to move to correspond to the limiting hole of the protection piece and weld.

After welding is completed, all mechanisms move reversely to reset, and blanking and repeated feeding are carried out.

Of course, the sequence numbers of S1-S10 are not the only limitation to the welding process, and for example, in other embodiments, the side plate may be placed between two limit blocks after the end face shaping mechanism shapes. Or the shaping sequence of the combination body formed by the battery core and the end plate can be adjusted according to other requirements. And the order of the side plate bottom supporting mechanism and the side plate end pressing mechanism can also be adjusted, or the reset of the side shaping mechanism can also be reset after the top pressing mechanism presses.

During welding, the position of the welding seam can be determined in a visual positioning mode, the automatic welding process of the whole device can be realized by combining a control device with various sensors, the visual positioning and the corresponding control technology are known technologies and are not innovation points of the scheme, and details are not described herein.

The utility model has a plurality of implementation modes, and all technical schemes formed by adopting equivalent transformation or equivalent transformation all fall within the protection scope of the utility model.

Claims (10)

1. Shaping device before electric core module assembly welding, its characterized in that: a plastic that is used for curb plate, end plate and electric core of electric core module, it includes

A carrier having a carrier plane;

the battery core end plate shaping mechanism is provided with a side surface shaping mechanism, an end surface shaping mechanism and a top pressing mechanism;

the side plate attaching mechanism is provided with a positioning space for placing the side plate and a structure for driving the side plate at the positioning space to be attached to the assembly of the shaped battery cell and the end plate on the loading platform;

a guard mechanism including a guard having a defined aperture facing the engagement seam of the side plate and the end plate, the guard being connected to a guard drive means which drives movement thereof into engagement with the end plate and/or the end flap of the side plate.

2. The pre-welding shaping device for the battery cell module set of claim 1, characterized in that: the side shaping mechanism and the top pressing mechanism are positioned on the same transfer mechanism, the transfer mechanism drives the side shaping mechanism and the top pressing mechanism to synchronously move between a first position and a second position, the top pressing mechanism is positioned above the carrier platform at the first position, and the top pressing mechanism is positioned outside the carrier platform at the second position.

3. The pre-welding shaping device for the battery cell module set of claim 1, characterized in that: the top pressing mechanism comprises a plurality of pressing pieces which are arranged in a close-proximity mode, each pressing piece is connected with a guide shaft extending longitudinally, the guide shafts movably penetrate through and are limited on the installation pieces, springs are sleeved on the peripheries of the guide shafts, one ends of the springs are connected with the pressing pieces, the other ends of the springs are connected with the installation pieces, and the installation pieces are connected with a lifting driving device for driving the installation pieces to lift.

4. The pre-welding shaping device for the battery cell module set of claim 3, characterized in that: the installed part includes with every compress tightly on the installation roof beam that the piece corresponds, installation roof beam detachably sets up on two side-mounting boards, the installation roof beam is hung and is established on the girder.

5. The pre-welding shaping device for the battery cell module set of claim 1, characterized in that: the positioning space comprises an L-shaped supporting plate and two limiting blocks positioned at two ends of the L-shaped supporting plate, and each limiting block is connected with a multi-directional driving device which drives the limiting blocks to move horizontally in a reciprocating mode along a first horizontal direction and a second horizontal direction.

6. The pre-welding shaping device for the battery cell module set of claim 5, characterized in that: the supporting plate is arranged on a supporting plate, and a sucking disc penetrating through the supporting plate is arranged on the supporting plate.

7. The pre-welding shaping device for the battery cell module set of claim 6, characterized in that: the two ends of the supporting plate extend out of the two ends of the supporting plate, the supporting plate further comprises a side plate end portion pressing mechanism, the side plate end portion pressing mechanism comprises pressing blocks corresponding to the parts, extending out of the supporting plate, and each pressing block is connected with a pressing driving device which drives the pressing driving device to reciprocate along a first horizontal direction and is tightly attached to the supporting plate.

8. The pre-welding shaping device for the battery cell module set of claim 1, characterized in that: the lifting device comprises a side plate bottom supporting mechanism, wherein the side plate bottom supporting mechanism comprises pressure heads positioned outside two sides of a carrying platform, the pressure heads are arranged on a bolt, the bolt is movably arranged on a support plate, and the support plate is connected with a lifting driving device for driving the support plate to lift.

9. The pre-welding shaping device for the battery cell module set according to any one of claims 1 to 8, characterized in that: the protection piece is also connected with an air pipe which is communicated with the limiting hole.

10. Welding equipment, its characterized in that: the device of any preceding shaping of battery core module welding of including claims 1-9.

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