CN117644288A - Welding equipment for electrode lugs of energy storage battery - Google Patents

Abstract

The invention discloses energy storage battery tab welding equipment, which comprises a laser welding manipulator, a welding device and a welding device, wherein the laser welding manipulator is arranged beside a rack module through a mounting bracket and is used for welding battery tabs; the flange end of the laser welding manipulator is provided with a laser welding module; and the frame module is provided with a lower pressing die set, and the lower pressing die set is used for pressing and positioning the energy storage battery. The welding device can accurately position the battery cell tab in the welding process and before welding, and ensures the stability and welding quality of the tab in the welding process.

Description

Welding equipment for electrode lugs of energy storage battery

Technical Field

The invention relates to welding equipment, in particular to energy storage battery tab welding equipment, and belongs to the technical field of energy storage.

Background

As a core material cell in the energy storage product, the welding quality and the welding effectiveness of the lug directly influence the performance and the safety of the energy storage product. If the energy storage battery is in the welding process, the positioning device is positioned inaccurately, so that the welding deviation of the tab is caused, the welding quality is poor, and the service life of the battery is influenced; if the dust removal work is not in place in the welding process, the tab cold welding can be caused, the defective rate of the battery tab can be increased, and the overall qualification rate of the battery is affected.

Disclosure of Invention

The invention aims to provide an energy storage battery tab welding device which can accurately position the battery tab during and before welding and ensure the stability and welding quality of the tab during welding.

In order to achieve the above object, the present invention adopts a technical scheme that an energy storage battery tab welding device comprises

-a laser welding robot arranged beside the frame module by means of a mounting bracket for welding battery tabs; the flange end of the laser welding manipulator is provided with a laser welding module;

-a lower press die set is arranged on the frame module, and the lower press die set is used for pressing down and positioning the energy storage battery.

Preferably, the rack module comprises a rack, a panel is arranged on the rack, a double-speed chain is arranged on the panel, a tray pressing cylinder is arranged on the outer side of the double-speed chain, and a tray pressing block is arranged at the output end of the tray pressing cylinder; the lifting electric cylinder is arranged on the panel in the middle of the speed doubling chain, a product supporting plate is arranged at the output end of the lifting electric cylinder, a first guide rod is further arranged between the product supporting plate and the panel, one end of the first guide rod is fixed at the bottom of the product supporting plate, the other end of the first guide rod is a free end, penetrates through the panel and moves up and down on the panel.

Preferably, a blocking cylinder is arranged beside the product supporting plate, and a positioning pin is arranged on the product supporting plate.

Preferably, the lower pressing die assembly comprises a lower mounting plate, the lower mounting plate is mounted on the panel, the lower mounting plate is provided with an upper fixing plate through a support column, and a middle mounting plate is arranged in the middle of the support column; the upper fixing plate is provided with a lower pressing cylinder, and the output end of the lower pressing cylinder is fixed on the middle mounting plate and drives the middle mounting plate to move up and down;

the copper nozzle fixture is arranged on the middle mounting plate through a fixture connecting plate, and a fixture pressing module is arranged on the fixture connecting plate.

Preferably, the tool pressing module comprises a tool pressing cylinder, the tool pressing cylinder is fixed on a mounting plate, the mounting plate is arranged on a tool connecting plate through a second guide rod, and the output end of the mounting plate is fixed on the tool connecting plate and drives the tool connecting plate to move up and down;

a group of side plate positioning cylinders and side plate clamping cylinders are respectively arranged on the tool connecting plates positioned on two sides of the tool pressing cylinder; the output end of the side plate positioning cylinder is provided with a side positioning plate through a connecting block; the output end of the side plate clamping cylinder is also provided with a side clamping plate through a connecting block; the side locating plate and the side clamping plate are located at the bottom of the tool connecting plate and are not in contact with the tool connecting plate.

Preferably, the side clamping plate is further provided with a second side plate clamping cylinder, and the output end of the second side plate clamping cylinder is provided with a push block; the two ends of the tool connecting plate are respectively provided with an end plate fixed cylinder, and the output ends of the end plate fixed cylinders are respectively provided with an end plate pushing block for positioning and pushing the end plates.

Preferably, the device further comprises a limiting pin, wherein the limiting pin penetrates through the tool connecting plate to be fixed on the middle mounting plate and is used for limiting the height of the upward movement of the tool connecting plate; and the tooling connecting plate is also provided with a locating pin, and the locating pin is matched with a locating hole on the product tray.

Preferably, the copper nozzle tool comprises a tool mounting plate, a plurality of welding copper nozzles are uniformly arranged in the middle of the tool mounting plate, and dust removing pipelines and air pipes are respectively arranged on two sides of the copper nozzle.

Preferably, the laser welding module comprises a laser welding mounting plate, wherein a vibrating mirror and an industrial camera are arranged on the laser welding mounting plate, and a light source is arranged below the industrial camera; the laser welding mounting plate is also provided with a rotary air cylinder, the movable end of the rotary air cylinder is provided with a baffle plate, and the baffle plate is positioned below the light source and used for blocking the light source; and the laser welding mounting plate is also provided with a laser range finder.

Preferably, a fire-fighting water tank is arranged beside the frame module.

The invention has the beneficial effects that: the welding equipment is used for welding the electrode lugs and the bus bars together, the battery module flows into the station along with the tray through the double-speed chain, the battery module is lifted in place by the lifting electric cylinder, the pressing module acts at the moment, the copper nozzle tool is driven to move downwards until the welding station is stopped, and the laser welding module is used for welding the battery electrode lugs. The lower pressing die set is provided with multiple positioning and regulating mechanisms, so that the positions of the electrode lugs and the battery busbar are fully ensured not to deviate, and the welding quality is ensured. Meanwhile, dust is removed in the welding process, dummy welding of the tab is placed, inert gas is introduced during welding, and oxidation is placed. The whole equipment is accurate in positioning and high in welding quality and accuracy.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings used in the description of the embodiments or the prior art will be briefly described below.

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

FIG. 2 is a schematic diagram of a rack module;

FIG. 3 is a schematic diagram of a pressing module;

FIG. 4 is a schematic structural diagram of a tooling press-down module;

FIG. 5 is a schematic side elevational view of FIG. 4;

FIG. 6 is a top view of FIG. 4;

FIG. 7 is a schematic view of the bottom structure of the soil 4;

FIG. 8 is a top view of FIG. 7;

FIG. 9 is a schematic structural view of a copper nozzle tooling;

FIG. 10 is a schematic diagram of a laser welding module;

fig. 11 is a schematic structural view of an energy storage cell (without a tray);

fig. 12 is a schematic view of the structure of an energy storage cell (with a tray).

Detailed Description

In order to make the technical solution in the present application better understood by those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

As shown in fig. 1, the welding device for the electrode lugs of the energy storage battery comprises a laser welding manipulator 4, a welding device and a welding device, wherein the laser welding manipulator is arranged beside a frame module 2 through a mounting bracket 5 and is used for welding the electrode lugs of the battery; the flange end of the laser welding manipulator 4 is provided with a laser welding module 1; the frame module 2 is provided with a lower pressing die set 3 which is used for pressing and positioning the energy storage battery.

As shown in fig. 2, the rack module 2 includes a rack 201, a panel 202 is disposed on the rack 201, a speed-doubling chain 206 is disposed on the panel 202, a tray pressing cylinder 203 is disposed outside the speed-doubling chain 203, and a tray pressing block 204 is disposed at an output end of the tray pressing cylinder 203; the lifting cylinder 211 is arranged on the panel positioned in the middle of the speed doubling chain 206, a product supporting plate 205 is arranged at the output end of the lifting cylinder 211, a first guide rod 210 is further arranged between the product supporting plate 205 and the panel 202, one end of the first guide rod 210 is fixed at the bottom of the product supporting plate 205, the other end is a free end, penetrates through the panel 202 and moves up and down on the panel.

A blocking cylinder 208 is arranged beside the product supporting plate 205, and a positioning pin 207 is arranged on the product supporting plate 205.

As shown in fig. 11 and 12, the energy storage battery 7 includes a plurality of electric cells 701, the electric cells 701 wrap a side plate 702 and an end plate 703, the electric cells 701 form an electric cell package, an integrated busbar 706 is covered on the electric cell package, and a busbar 705 is covered on a tab 704.

The energy storage battery 7 is placed on the product tray 10, and the energy storage battery 7 is brought into the welding station by the product tray 10.

The work flow of this patent is:

(1) the product tray 10 carries the energy storage cells 7 through the speed chain 206 into the product support plate 205;

(2) the product support plate 205 rises to the welding station under the lifting of the lifting cylinder 211;

(3) the lower pressing die set 3 descends to the surface of the energy storage battery 7, and positions and regulates the periphery of the energy storage battery respectively;

(4) the copper nozzle tooling 9 pre-presses and positions the upper surface of the energy storage battery 7;

(5) the laser welding manipulator 4 drives the laser welding module 1 to weld the lug of the energy storage battery;

(6) after the welding is finished, the lifting electric cylinder 211 descends, the energy storage battery 7 falls to the double-speed chain, and then the energy storage battery is returned to be transported to the next station by the original path of the double-speed chain, and the whole process is finished.

(7) If fire occurs in the welding process of the energy storage battery, the fire-extinguishing water tank 6 is directly conveyed by the speed-doubling chain to extinguish the fire.

As shown in fig. 3 to 8, the lower die set 3 includes a lower mounting plate 301, the lower mounting plate 301 is mounted on the panel 202, the lower mounting plate 301 is provided with an upper fixing plate 304 through a support column 302, and an intermediate mounting plate 303 is disposed at an intermediate position of the support column 302; the upper fixing plate 304 is provided with a lower pressing cylinder 305, and the output end of the lower pressing cylinder 305 is fixed on the middle mounting plate 303 and drives the middle mounting plate 303 to move up and down;

the middle mounting plate 303 is provided with a copper nozzle tool 9 through a tool connecting plate 306, and the tool connecting plate 306 is provided with a tool pressing module 8.

The tooling pressing module 8 comprises a tooling pressing cylinder 801, wherein the tooling pressing cylinder 801 is fixed on a mounting plate 802, the mounting plate 802 is arranged on a tooling connecting plate 306 through a second guide rod 803, and the output end of the mounting plate 802 is fixed on the tooling connecting plate 306 and drives the tooling connecting plate 306 to move up and down;

a group of side plate positioning air cylinders 804 and side plate clamping air cylinders 805 are respectively arranged on the tool connecting plates 306 positioned on two sides of the tool pressing air cylinder 801; the output end of the side plate positioning cylinder 804 is provided with a side positioning plate 807 through a connecting block 806; the output end of the side plate clamping cylinder 805 is also provided with a side clamping plate 808 through a connecting block 806; the side positioning plate 807 and side clamping plate 808 are located at the bottom of tooling web 306 and are not in contact with tooling web 306.

The side clamping plate 808 is further provided with a second side plate clamping cylinder 809, and the output end of the second side plate clamping cylinder 809 is provided with a push block 810; the two ends of the tooling connecting plate 306 are respectively provided with an end plate fixing cylinder 811, and the output ends of the end plate fixing cylinders 811 are respectively provided with an end plate pushing block 812 for positioning and pushing the end plates.

The device further comprises a limiting pin 813, wherein the limiting pin 813 penetrates through the tool connecting plate 306 to be fixed on the middle mounting plate 303 and is used for limiting the height of the upward movement of the tool connecting plate 306; the tooling connecting plate 306 is also provided with a locating pin 814, and the locating pin 814 is matched with a locating hole on a product tray.

In the technical scheme, the method comprises the following steps:

(1) the lower pressure cylinder 305 acts first to drive the middle mounting plate 303 to descend to the surface of the energy storage battery 7;

(2) then, the side plate positioning air cylinder 804 moves to the side plate 702 of the energy storage battery 7 with the side positioning plate 807 to position the energy storage battery;

(3) the side plate clamping cylinder 805 drives the side clamping plate 808 to act, the side plate 702 is clamped, and at the moment, the second side plate clamping cylinder 809 drives the pushing block 810 to act due to the limit of the travel of the side plate clamping cylinder 805, so that the side plate is secondarily positioned;

(4) the end plate fixing cylinders 811 located on both sides operate to fix and position the end plate 703;

(5) after the energy storage battery 7 is positioned, the tooling pressing cylinder 801 acts to drive the copper nozzle tooling 9 on the tooling pressing cylinder to run to the surface of the energy storage battery 7, and the welding part of the tab is flattened and compacted;

(6) and then the tab and the bus bar are welded by the laser welding module 1.

In the technical scheme, the tooling connecting plate 306 is also provided with a locating pin 814, so that the blind copper nozzle tooling is convenient to replace.

Still include spacer 813, the spacer 813 passes frock connecting plate 306 and fixes on middle mounting panel 303 for to the upward movement restriction height of frock connecting plate 306, frock cylinder 801 action carries out the height restriction in the in-process of rising back down.

As shown in fig. 9, the copper nozzle fixture 9 includes a fixture mounting plate 901, a plurality of welding copper nozzles 902 are uniformly arranged in the middle of the fixture mounting plate 901, and dust removal pipes 903 and air pipes 904 are respectively arranged on two sides of the copper nozzles 902.

In this technical scheme, let in inert gas in the welding process in order to prevent welding oxidation, the nitrogen gas of priority lets in this patent, in the current energy storage battery tab welding machine equipment, the condition of no nitrogen gas lets in, this equipment lets in nitrogen gas can effectively prevent oxidation, guarantees welding quality.

Meanwhile, in the welding process, dust and welding slag are removed from the welding station, and the phenomenon of cold joint of the tab is prevented. And the qualification rate of the energy storage battery is effectively ensured.

As shown in fig. 10, the laser welding module 1 includes a laser welding mounting plate 101, a galvanometer 102 and an industrial camera 103 are disposed on the laser welding mounting plate 101, and a light source 104 is disposed below the industrial camera 103; the laser welding mounting plate 101 is also provided with a rotary cylinder 105, the movable end of the rotary cylinder 105 is provided with a baffle 106, and the baffle 106 is positioned below the light source 104 and used for blocking the light source; the laser welding mounting plate 101 is also provided with a laser range finder 107.

In this patent, welding speed and quality have been improved greatly through the galvanometer welding.

The fire-fighting water tank 6 is arranged beside the frame module 2, so that the energy storage battery is prevented from being in fire disaster in the welding process.

The described embodiments are only some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Claims (10)

1. The utility model provides an energy storage battery tab welding equipment which characterized in that includes

-a laser welding robot (4) arranged beside the frame module (2) by means of a mounting bracket (5) for welding battery lugs; the flange end of the laser welding manipulator (4) is provided with a laser welding module (1);

-a lower press die set (3) is arranged on the frame module (2) for pressing down and positioning the energy storage battery.

2. The energy storage battery tab welding equipment according to claim 1, wherein the rack module (2) comprises a rack (201), a panel (202) is arranged on the rack (201), a speed doubling chain (206) is arranged on the panel (202), a tray pressing cylinder (203) is arranged on the outer side of the speed doubling chain (203), and a tray pressing block (204) is arranged at the output end of the tray pressing cylinder (203); be located be provided with jacking jar (211) on the panel in the middle of doubly fast chain (206), the output of jacking jar (211) is provided with product backup pad (205), still be provided with first guide bar (210) between product backup pad (205) and panel (202), first guide bar (210) one end is fixed in product backup pad (205) bottom, and the other end is the free end, runs through panel (202) and reciprocates at the panel.

3. The energy storage battery tab welding apparatus of claim 2 wherein a blocking cylinder (208) is disposed beside the product support plate (205), and a locating pin (207) is disposed on the product support plate (205).

4. The energy storage battery tab welding apparatus according to claim 1 or 2, wherein the pressing down module (3) comprises a lower mounting plate (301), the lower mounting plate (301) is mounted on the panel (202), the lower mounting plate (301) is provided with an upper fixing plate (304) through a support column (302), and an intermediate mounting plate (303) is disposed at an intermediate position of the support column (302); the upper fixing plate (304) is provided with a lower pressing cylinder (305), and the output end of the lower pressing cylinder (305) is fixed on the middle mounting plate (303) and drives the middle mounting plate (303) to move up and down;

the copper nozzle tooling (9) is arranged on the middle mounting plate (303) through a tooling connecting plate (306), and a tooling pressing module (8) is arranged on the tooling connecting plate (306).

5. The welding equipment for the electrode lugs of the energy storage battery according to claim 4, wherein the tooling pressing module (8) comprises a tooling pressing cylinder (801), the tooling pressing cylinder (801) is fixed on a mounting plate (802), the mounting plate (802) is arranged on a tooling connecting plate (306) through a second guide rod (803), and the output end of the mounting plate is fixed on the tooling connecting plate (306) and drives the tooling connecting plate (306) to move up and down;

a group of side plate positioning cylinders (804) and side plate clamping cylinders (805) are respectively arranged on the tool connecting plates (306) positioned on two sides of the tool pressing cylinder (801); the output end of the side plate positioning cylinder (804) is provided with a side positioning plate (807) through a connecting block (806); the output end of the side plate clamping cylinder (805) is also provided with a side clamping plate (808) through a connecting block (806); the side positioning plate (807) and the side clamping plate (808) are positioned at the bottom of the tooling connecting plate (306) and are not in contact with the tooling connecting plate (306).

6. The energy storage battery tab welding equipment according to claim 5, wherein a second side plate clamping cylinder (809) is further arranged on the side clamping plate (808), and a pushing block (810) is arranged at the output end of the second side plate clamping cylinder (809); the two ends of the tooling connecting plate (306) are respectively provided with an end plate fixed cylinder (811), and the output ends of the end plate fixed cylinders (811) are respectively provided with an end plate pushing block (812) for positioning and pushing the end plates.

7. The energy storage battery tab welding apparatus of claim 6, further comprising a limit pin (813), the limit pin (813) being fixed to the intermediate mounting plate (303) through the tooling connection plate (306) for limiting the height of the tooling connection plate (306) for upward movement; and the tooling connecting plate (306) is also provided with a locating pin (814), and the locating pin (814) is matched with a locating hole on the product tray for use.

8. The welding equipment for the electrode lugs of the energy storage battery according to claim 3, wherein the copper nozzle tool (9) comprises a tool mounting plate (901), a plurality of welding copper nozzles (902) are uniformly arranged in the middle of the tool mounting plate (901), and dust removing pipelines (903) and air pipes (904) are respectively arranged on two sides of the copper nozzles (902).

9. The energy storage battery tab welding equipment according to claim 1, wherein the laser welding module (1) comprises a laser welding mounting plate (101), a vibrating mirror (102) and an industrial camera (103) are arranged on the laser welding mounting plate (101), and a light source (104) is arranged below the industrial camera (103); the laser welding device comprises a laser welding mounting plate (101), and is characterized in that a rotary cylinder (105) is further arranged on the laser welding mounting plate, a baffle (106) is arranged at the movable end of the rotary cylinder (105), and the baffle (106) is positioned below a light source (104) and used for blocking the light source; and a laser distance meter (107) is further arranged on the laser welding mounting plate (101).

10. The welding equipment for the pole lugs of the energy storage battery according to claim 1, wherein a fire-fighting water tank (6) is further arranged beside the frame module (2).