CN116525954A

CN116525954A - High-speed cutting and stacking integrated machine

Info

Publication number: CN116525954A
Application number: CN202310273114.2A
Authority: CN
Inventors: 余涛; 陈诚; 赵海殿
Original assignee: Linton Kayex Technology Co Ltd
Current assignee: Linton Kayex Technology Co Ltd
Priority date: 2023-03-17
Filing date: 2023-03-17
Publication date: 2023-08-01

Abstract

The invention discloses a high-speed cutting and stacking integrated machine, which relates to the technical field of lithium battery production equipment; the lamination table and the lamination clamping jaw mechanism are arranged at the left end of the positioning and transplanting mechanism, and pole pieces on the positioning and transplanting mechanism are grabbed onto the lamination table through the lamination clamping jaw mechanism to carry out lamination on the diaphragm; the lamination component adopts a continuous lamination mode of four pole pieces, so that the waste beat caused by taking and re-lamination of the monopole pieces is reduced; the invention breaks through the problems of the traditional lamination machine in the lithium battery industry such as bottleneck in lamination efficiency, large floor area of the machine, difficult operation and maintenance and the like, adopts a lamination mode of four pole pieces, improves the productivity of single-machine equipment, improves the production efficiency of the equipment, has compact structure of the machine, small floor area of the equipment, saves the floor area of the equipment and reduces the production cost of the equipment.

Description

High-speed cutting and stacking integrated machine

Technical Field

The invention belongs to the technical field of lithium battery production equipment, and particularly relates to a high-speed cutting and stacking integrated machine.

Background

The lithium battery has the advantages of high voltage, high energy density, high safety, low self-discharge rate and the like, and is a promising new energy source; with further development of science and technology, lithium batteries are increasingly demanded.

In lithium battery production process, the pole piece is required to be cut and laminated, the whole line production capacity and the manufacturing cost of the battery cell are directly determined by the speed of the cutting and lamination, the pole piece cutting machine and the lithium battery lamination machine are usually separate different machines, the cut pole piece is conveyed to the lamination machine for lamination in the middle through a production line conveying mode, the existing cutting and lamination integrated machine can only take a single pole piece for lamination, the equipment beat is relatively slow, the production efficiency is low, the production capacity is improved, a plurality of cutting and lamination integrated machines are required to be simultaneously produced in order to meet market demands, the occupied area of the plurality of cutting and lamination integrated machines is large, and the equipment cost is high.

Disclosure of Invention

To solve the defects and the shortages of the prior art; the invention aims to provide a high-speed cutting and stacking integrated machine which is simple in structure, reasonable in design and convenient to use, adopts a lamination mode of four pole pieces, improves the productivity of single-machine equipment, improves the production efficiency of the equipment, is compact in structure, occupies small area, saves the occupied area and reduces the production cost of the equipment.

In order to achieve the above purpose, the invention adopts the following technical scheme: the feeding mechanism comprises a feeding mechanism; the feeding mechanism is arranged on the right side of the mechanism and is used for unreeling pole piece coiled materials and diaphragms;

a slicing mechanism; the cutting device is used for cutting off the R angle of the pole piece and cutting off the adjacent pole piece;

a vacuum conveying line; the vacuum conveying line is used for conveying the pole pieces;

positioning a transplanting mechanism; the positioning and transplanting mechanism is used for transplanting and positioning the pole pieces, and the pole pieces conveyed on the vacuum conveying line are taken by a manipulator and placed in the positioning and transplanting mechanism for transplanting and positioning;

lamination table and lamination clamping jaw mechanism; the lamination table and the lamination clamping jaw mechanism are arranged at the left end of the positioning and transplanting mechanism, and pole pieces on the positioning and transplanting mechanism are grabbed onto the lamination table through the lamination clamping jaw mechanism to carry out lamination on the diaphragm; the lamination component adopts a continuous lamination mode of four pole pieces, so that the waste beat caused by taking and re-lamination of the monopole pieces is reduced;

the post-treatment mechanism is arranged at the rear sides of the lamination table and the lamination clamping jaw mechanism and is used for carrying out subsequent treatment on the overlapped pole pieces and diaphragms and comprises a hot cutting mechanism, an adhesive tape sticking mechanism, a hot pressing mechanism and a blanking mechanism; the hot cutting mechanism is used for cutting the quadrupoles through the hot cutting mechanism, the tape sticking mechanism is used for sticking the cut battery cells with adhesive tapes, the battery cell taking manipulator is used for taking the battery cells to the tape sticking mechanism for rubberizing after the cutting is completed, the battery cells are transplanted to the hot pressing mechanism for hot pressing after rubberizing is completed, and the discharging manipulator is used for taking the battery cells to a belt line of the discharging mechanism after the hot pressing is completed.

Preferably, the feeding mechanism comprises a positive plate unreeling module, a negative plate unreeling module, a diaphragm unreeling module, a deviation correcting mechanism, a defect detecting mechanism and a tension control mechanism; the positive plate unreeling module and the negative plate unreeling module are arranged up and down oppositely, and the diaphragm unreeling module is located between the positive plate unreeling module and the negative plate unreeling module, the positive plate unreeling module is used for unreeling a positive plate coiled material, the negative plate unreeling module is used for unreeling a negative plate coiled material, the diaphragm unreeling module is used for unreeling a diaphragm coiled material, and a correction mechanism, a defect detection mechanism and a tension control mechanism are sequentially arranged on the conveying direction of the positive plate coiled material and the negative plate coiled material.

Preferably, the slicing mechanism comprises an anode slice cutting R angle, a cutting cutter, a cathode slice cutting R angle and a cutting cutter, wherein the anode slice cutting R angle, the cutting cutter, the cathode slice cutting R angle and the cutting cutter are arranged in the conveying direction of the anode slice coiled material in an up-down opposite mode.

Preferably, the vacuum conveying line comprises a positive plate vacuum belt line and a negative plate vacuum belt line, and the positive plate vacuum belt line and the negative plate vacuum belt line are arranged in the conveying direction of the diaphragm coil in an up-down opposite mode.

Preferably, the positioning and transplanting mechanism comprises a positive plate secondary positioning table and transplanting mechanism and a negative plate secondary positioning table and transplanting mechanism, and the positive plate secondary positioning table and transplanting mechanism and the negative plate secondary positioning table and the transplanting mechanism are kept in vertical opposite arrangement.

Preferably, the defect detection mechanism detects the pole piece through a linear array camera to ensure that the pole piece transmitted in the past is a qualified product.

Preferably, the correcting mechanism and the tension control mechanism are used for correcting side errors in the transfer motion of the unreeled coiled material, so that accurate transfer can be ensured.

Compared with the prior art, the invention has the beneficial effects that: the invention breaks through the problems of the traditional lamination machine in the lithium battery industry such as bottleneck in lamination efficiency, large floor area of the machine, difficult operation and maintenance and the like, adopts a lamination mode of four pole pieces, improves the productivity of single-machine equipment, improves the production efficiency of the equipment, has compact structure of the machine, small floor area of the equipment, saves the floor area of the equipment and reduces the production cost of the equipment.

Drawings

For ease of illustration, the invention is described in detail by the following detailed description and the accompanying drawings.

Fig. 1 is a schematic structural view of the present invention.

In the figure: positive sheet unreeling module 11, negative sheet unreeling module 12, diaphragm unreeling module 13, correction mechanism 14, defect detection mechanism 15, positive sheet cutting R angle and cutting knife 21, negative sheet cutting R angle and cutting knife 22, positive sheet vacuum belt line 31, negative sheet vacuum belt line 32, positive sheet secondary positioning table and transplanting mechanism 41, negative sheet secondary positioning table and transplanting mechanism 42, lamination table and lamination clamping jaw mechanism 50, hot cutting mechanism 60, tape sticking mechanism 70, hot pressing mechanism 80, and blanking mechanism 90.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, the present invention is described below by means of specific embodiments shown in the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the invention. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present invention.

It should be noted here that, in order to avoid obscuring the present invention due to unnecessary details, only structures and/or processing steps closely related to the solution according to the present invention are shown in the drawings, while other details not greatly related to the present invention are omitted.

As shown in fig. 1, the present embodiment adopts the following technical scheme: the feeding mechanism comprises a feeding mechanism; the feeding mechanism is arranged on the right side of the mechanism and is used for unreeling pole piece coiled materials and diaphragms;

lamination table and lamination jaw mechanism 50; the lamination table and the lamination clamping jaw mechanism 50 are arranged at the left end of the positioning and transplanting mechanism, and pole pieces on the positioning and transplanting mechanism are grabbed onto the lamination table through the lamination clamping jaw mechanism to carry out lamination on the diaphragm; the lamination component adopts a continuous lamination mode of four pole pieces, so that the waste beat caused by taking and re-lamination of the monopole pieces is reduced;

the post-processing mechanism is arranged at the rear side of the lamination table and the lamination clamping jaw mechanism 50 and is used for carrying out subsequent processing on the overlapped pole pieces and diaphragms and comprises a hot cutting mechanism 60, an adhesive tape sticking mechanism 70, a hot pressing mechanism 80 and a blanking mechanism 90; the hot cutting mechanism 60 is arranged at the rear side of the lamination table and the lamination clamping jaw mechanism 50, the quadrupole plates are cut through the hot cutting mechanism 60, the tape pasting mechanism 70 is used for pasting the cut battery cells with tapes, the battery cells are taken to the tape pasting mechanism 70 by the battery cell taking manipulator after cutting, the tape pasting is carried out, the battery cells are transplanted to the hot pressing mechanism 80 for hot pressing after the tape pasting is finished, and the battery cells are taken to the belt line of the blanking mechanism 90 by the blanking manipulator after the hot pressing is finished.

Further, the feeding mechanism comprises a positive plate unreeling module 11, a negative plate unreeling module 12, a diaphragm unreeling module 13, a deviation correcting mechanism 14, a defect detecting mechanism 15 and a tension control mechanism; the device comprises a positive plate unreeling module 11, a negative plate unreeling module 12 and a diaphragm unreeling module 13, wherein the positive plate unreeling module 11 and the negative plate unreeling module 12 are arranged vertically oppositely, the positive plate unreeling module 11 is used for unreeling a positive plate coiled material, the negative plate unreeling module 12 is used for unreeling a negative plate coiled material, the diaphragm unreeling module 13 is used for unreeling a diaphragm coiled material, and a correction mechanism 14, a defect detection mechanism 15 and a tension control mechanism are sequentially arranged in the conveying direction of the positive plate coiled material and the negative plate coiled material; the defect detection mechanism 15 detects the pole piece through a linear array camera to ensure that the pole piece transmitted in the past is a qualified product; the correction mechanism 14 and the tension control mechanism are used for correcting side errors in the transfer motion of the unreeled coiled material, so that accurate transfer can be ensured.

Further, the slicing mechanism comprises an anode slice cutting R angle and a cutting cutter 21, and a cathode slice cutting R angle and a cutting cutter 22, wherein the anode slice cutting R angle and the cutting cutter 21, the cathode slice cutting R angle and the cutting cutter 22 are vertically and oppositely arranged in the conveying direction of the anode slice coiled material.

Further, the vacuum conveying line comprises a positive plate vacuum belt line 31 and a negative plate vacuum belt line 32, and the positive plate vacuum belt line 31 and the negative plate vacuum belt line 32 are arranged in the conveying direction of the diaphragm coil in an up-down opposite mode.

Further, the positioning and transplanting mechanism comprises a positive plate secondary positioning table and transplanting mechanism 41 and a negative plate secondary positioning table and transplanting mechanism 42, and the positive plate secondary positioning table and transplanting mechanism 41 and the negative plate secondary positioning table and the transplanting mechanism 42 are kept in vertical opposite arrangement.

The working principle of the specific embodiment is as follows: first,: the positive and negative electrode rolls pass through a deviation correcting mechanism 14, a defect detecting mechanism 15 and a tension control mechanism to the cutter position to match vision to cut an R angle and cut a pole piece, the pole piece is transferred through a vacuum belt after being cut off and subjected to size detection (NG is thrown to a NG box), iron and dust removal are carried out, the pole piece is taken to a positive material taking standby position, a material taking module is used for taking 2 pole pieces (positive 2 pieces and negative 2 pieces) to a secondary positioning table and a transplanting mechanism to carry out vision detection, and the deviation correcting platform is used for correcting and compensating after the vision detection is finished; after correction is completed, a pole piece (an anode 2 piece and a cathode 2 piece) is taken by a material taking manipulator, after the pole piece is taken, the material taking manipulator is transplanted to a handover position, a pole piece on the material taking manipulator is clamped by a lamination clamping jaw, the pole piece is transplanted to a lamination table for lamination, a diaphragm is positioned between the anode and the cathode pole pieces, and diaphragm feeding is performed under the action of the lamination clamping jaw and a suction plate by adopting a tension control, buffer device and a correction mechanism; and after lamination is completed, the lamination is mechanically cut by a hot cutting mechanism, after the cutting is completed, the battery core is taken to a rubberizing position by a battery core taking manipulator for rubberizing, after rubberizing is completed, the lamination is transplanted to a hot pressing station for hot pressing, and after hot pressing is completed, the battery core is taken to a blanking belt line by a blanking manipulator.

The invention adopts a high-precision tension and deviation correcting functional mechanism, adopts high-precision visual detection, and improves the cutting and positioning precision of the pole piece; the lamination part adopts a continuous and uninterrupted lamination mode of four pole pieces, so that the waste beat caused by taking the monopole pieces and laminating again is reduced, the whole structure of the equipment is compact, the occupied area of the equipment is greatly reduced, the production efficiency of the equipment is improved, and the production cost of the equipment is reduced.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims

1. High-speed cutting and stacking all-in-one, its characterized in that: it comprises

A feeding mechanism; the feeding mechanism is arranged on the right side of the mechanism and is used for unreeling pole piece coiled materials and diaphragms;

2. The high-speed dicing and stacking all-in-one machine according to claim 1, wherein: the feeding mechanism comprises a positive plate unreeling module, a negative plate unreeling module, a diaphragm unreeling module, a correction mechanism, a defect detection mechanism and a tension control mechanism; the positive plate unreeling module and the negative plate unreeling module are arranged up and down oppositely, and the diaphragm unreeling module is located between the positive plate unreeling module and the negative plate unreeling module, the positive plate unreeling module is used for unreeling a positive plate coiled material, the negative plate unreeling module is used for unreeling a negative plate coiled material, the diaphragm unreeling module is used for unreeling a diaphragm coiled material, and a correction mechanism, a defect detection mechanism and a tension control mechanism are sequentially arranged on the conveying direction of the positive plate coiled material and the negative plate coiled material.

3. The high-speed dicing and stacking all-in-one machine according to claim 1, wherein: the slicing mechanism comprises an anode slice cutting R angle, a cutting cutter, a cathode slice cutting R angle and a cutting cutter, wherein the anode slice cutting R angle, the cutting cutter, the cathode slice cutting R angle and the cutting cutter are oppositely arranged in the conveying direction of the anode slice coiled material.

4. The high-speed dicing and stacking all-in-one machine according to claim 1, wherein: the vacuum conveying line comprises a positive plate vacuum belt line and a negative plate vacuum belt line, and the positive plate vacuum belt line and the negative plate vacuum belt line are arranged in the conveying direction of the diaphragm coil in an up-down opposite mode.

5. The high-speed dicing and stacking all-in-one machine according to claim 1, wherein: the positioning and transplanting mechanism comprises a positive plate secondary positioning table and transplanting mechanism and a negative plate secondary positioning table and transplanting mechanism, and the positive plate secondary positioning table and transplanting mechanism and the negative plate secondary positioning table and the transplanting mechanism are kept in vertical opposite arrangement.

6. The high-speed dicing and stacking all-in-one machine according to claim 2, wherein: the defect detection mechanism detects the pole piece through the linear array camera, and ensures that the pole piece transmitted in the past is a qualified product.

7. The high-speed dicing and stacking all-in-one machine according to claim 2, wherein: the correction mechanism and the tension control mechanism are used for correcting side errors in the transfer motion of the unreeled coiled material, so that accurate transfer can be ensured.