CN221678303U - Glue point printing detection mechanism for battery piece and production device - Google Patents

Abstract

The utility model discloses a glue point printing detection mechanism for a battery piece, which comprises a first surface printing detection assembly and a second surface printing detection assembly, and a turnover assembly movably arranged between the first surface printing detection assembly and the second surface printing detection assembly; the first surface printing detection assembly and the second surface printing detection assembly comprise a correction mechanism, a transfer mechanism and a glue point detection mechanism which are sequentially arranged; the offset printing mechanism is movably arranged above the transfer mechanism. The utility model also discloses a production device for the battery piece. According to the utility model, the battery piece is subjected to double-sided dispensing operation, so that the breaking rate of the thin battery piece can be reduced to a certain extent.

Description

Glue point printing detection mechanism for battery piece and production device

Technical Field

The utility model relates to the technical field of printing glue spot detection mechanisms, in particular to a glue spot printing detection mechanism for a battery piece and a production device.

Background

In recent years, along with the continuous rising of the price of silicon materials for photovoltaic, the reduction of the consumption of the silicon materials is one of important means for reducing the cost of the photovoltaic industry, and the thickness reduction of a battery piece is the inevitable direction and industry consensus of the cost reduction of the silicon materials. However, after the thickness of the battery piece is thinned, if the traditional welding strip and the battery piece are directly connected and welded at high temperature to form a string, the breaking rate of the battery piece is greatly improved, so that the production yield of the thin battery piece is reduced; therefore, the glue point printing detection mechanism and the production device for the battery piece are provided, and are used for solving the problem that the existing thin battery piece is high in breaking rate.

Disclosure of utility model

The utility model aims to provide a glue point printing detection mechanism and a production device for a battery piece, so as to solve the problem of high breaking rate of the conventional thin battery piece.

The utility model relates to a glue point printing detection mechanism for a battery piece and a production device, which can be realized by the following technical scheme:

The utility model relates to a glue point printing detection mechanism for a battery piece, which comprises a first surface printing detection assembly and a second surface printing detection assembly, and a turnover assembly movably arranged between the first surface printing detection assembly and the second surface printing detection assembly; the first surface printing detection assembly and the second surface printing detection assembly comprise a correction mechanism, a transfer mechanism and a glue point detection mechanism which are sequentially arranged; the offset printing mechanism is movably arranged above the transfer mechanism; the correction mechanism performs correction operation on the battery piece arranged on the correction mechanism; the transfer mechanism transfers the corrected battery piece to a printing position of the transfer mechanism, and transfers the printed battery piece to the glue point detection mechanism; the offset printing mechanism performs offset printing operation on the battery piece arranged on the printing position of the transfer mechanism; the glue point detection mechanism carries out glue point detection operation on the battery piece arranged on the glue point detection mechanism.

In one embodiment, the correction mechanism comprises a support table, a movable plate, a transverse motion correction device and a longitudinal motion correction device; the supporting table is a supporting main body; the movable plate is movably arranged on the supporting table; the transverse motion correcting device and the longitudinal motion correcting device are respectively arranged on the supporting table and are respectively connected with the movable plate in a transmission way.

In one embodiment, the transfer mechanism comprises a printing platform, a fork carriage handling assembly, and a translating plate assembly; the printing platform is fixedly arranged on the side edge of the correcting mechanism; the fork support carrying assembly and the translation plate assembly are respectively and movably arranged on the printing platform.

In one embodiment, the fork support carrying assembly comprises a mounting frame, a transverse moving device, a transfer table and a lifting moving device; the mounting frame is fixedly arranged on the printing platform; the transverse moving device is arranged on the mounting frame; the transfer table is movably arranged on the mounting frame and is in transmission connection with the transverse movement device; the lifting movement device is arranged on the mounting frame and is in transmission connection with the transfer table.

In one embodiment, the offset printing mechanism comprises a lifting assembly, a printing screen, a first lateral motion assembly, a doctor lifting assembly, and a printing doctor assembly; the lifting component is arranged at the side edge of the printing platform; the printing screen is arranged on the lifting assembly; the first transverse movement assembly is movably arranged on the printing screen; the scraper lifting assembly is movably arranged on the first transverse movement assembly; the printing scraper component is arranged below the scraper lifting component and can be in contact connection with the printing screen, and the first transverse movement component and the scraper lifting component are matched to drive the printing scraper component to move.

In one embodiment, two printing cavities are arranged on the printing screen, a plurality of glue holes penetrate through the printing cavities, and the positions of the glue holes respectively correspond to the positions of corresponding glue dispensing positions on the battery piece.

In one embodiment, the glue spot detection mechanism comprises a detection platform, a fixing frame and a photographing detection assembly; the detection platform is fixedly arranged on one side of the transfer mechanism; the fixing frame is fixedly arranged on the side edge of the detection platform; the photographing detection assembly is fixedly arranged on the fixing frame and is arranged right above the detection platform.

In one embodiment, the turnover assembly comprises a support frame, a turnover power assembly, a rotating shaft and at least one turnover rod; the support frame is fixedly arranged on the side edge of the glue point detection mechanism in the first surface printing detection assembly; the overturning power assembly is arranged on the supporting frame; the rotating shaft is movably arranged on the supporting frame and is in transmission connection with the overturning power component; at least one overturning rod is fixedly arranged on the rotating shaft.

In one embodiment, the roll-over power assembly includes a rotating electrical machine and a decelerator; the speed reducer is arranged on the supporting frame and is respectively in transmission connection with the rotating motor and the rotating shaft.

A production device for a battery sheet comprising the glue dot printing detection mechanism of any one of the above.

Compared with the prior art, the glue point printing detection mechanism and the production device for the battery piece have the beneficial effects that:

According to the glue point printing detection mechanism and the production device for the battery piece, full automation is realized through turning and positioning in the process of printing the front face and the back face of the battery piece, the production efficiency is greatly improved, the production cost is reduced, and the problem of higher breaking rate of the conventional thin battery piece is solved to a certain extent; in the process of conveying the battery pieces, a fork support mode is adopted, so that the conveying speed is greatly improved, the structure is simplified, the production efficiency of products is improved, and the cost is reduced; meanwhile, the mesh positions and the sizes of the printing screen plates are controlled, so that the glue amount printed on the battery piece is proper and the position is accurate, the bonding firmness of the subsequent welding strip is improved, and the welding strip is in close contact with the battery piece to enable the battery piece to obtain better battery piece performance.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present utility model and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic structural view of a spot-printing detection mechanism for a battery sheet according to the present utility model, including a correction mechanism, a transfer mechanism, a spot-printing mechanism, a spot-detecting mechanism, and a turnover assembly;

FIG. 2 is a schematic diagram of a calibration mechanism in the adhesive printing detection mechanism for a battery plate according to the present utility model shown in FIG. 1;

FIG. 3 is a schematic view of a transfer mechanism in the adhesive dot printing detection mechanism for a battery sheet of the present utility model shown in FIG. 1, including a fork carriage handling assembly;

FIG. 4 is a schematic view of the fork carriage assembly of FIG. 3;

FIG. 5 is a schematic view of a spot-printing mechanism of the spot-printing detection mechanism for a battery sheet of the present utility model shown in FIG. 1;

FIG. 6 is a schematic view of a glue dot detecting mechanism in the glue dot printing detecting mechanism for a battery sheet according to the present utility model shown in FIG. 1;

fig. 7 is a schematic structural view of a turnover assembly in the glue dot printing detection mechanism for a battery sheet according to the present utility model shown in fig. 1.

The figures indicate: 10, printing a detection assembly on a first surface; 11, a correction mechanism; 111, a support table; 112, a movable plate; 1121, a first tank; 113, a lateral motion correction device; 114, longitudinal motion correction means; 12, a transfer mechanism; 121, a printing platform; 122, a fork carriage handling assembly; 1221, a mounting rack; 12211, a slide rail; 1222, traversing motion means; 1223, a transfer station; 12231, vacuum suction nozzles; 1224, a lifting motion device; 123, translating the plate assembly; 13, a spot offset printing mechanism; 131, a lifting assembly; 132, printing a screen; 1321, printing chamber; 133, a first lateral motion assembly; 134, a scraper lifting assembly; 135, a printing doctor assembly; 14, a glue point detection mechanism; 141, a detection platform; 1411, a second tank; 142, a fixing frame; 143, a photographing detection assembly; 20, turning over the assembly; 21, a supporting frame; 22, turning over the power assembly; 221, a rotating electric machine; 222, a decelerator; 23, a rotating shaft; 24, turning the rod; 30, printing a detection component on the second surface; 40, battery piece.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1, a glue dot printing detection mechanism for a battery sheet according to the present utility model mainly includes a first side printing detection assembly 10, a turnover assembly 20, and a second side printing detection assembly 30; the turnover component 20 is movably arranged between the first surface printing detection component 10 and the second surface printing detection component 30, and is used for turning over the battery piece 40 subjected to printing detection by the first surface printing detection component 10 by 180 degrees to the second surface printing detection component 30 for printing detection operation. In this embodiment, the first side printing detection assembly 10 performs offset printing and glue spot detection on the two battery pieces 40 synchronously, and then the turnover assembly 20 rolls over 180 degrees of the two battery pieces 40 to the second side printing detection assembly 30 for offset printing and glue spot detection; in other embodiments, the number of the battery pieces 40 may be one, three or other plural, and the number of the battery pieces may be set according to actual needs, and then the first side printing detection assembly 10, the flipping assembly 20 and the second side printing detection assembly 30 are correspondingly adapted according to the actual number of the battery pieces 40.

Referring to fig. 1, in the present embodiment, the first side printing detection assembly 10 includes a correction mechanism 11, a transfer mechanism 12, a spot printing mechanism 13, and a spot detecting mechanism 14; the correction mechanism 11 performs a correction operation on the battery piece 40 provided thereon; the transfer mechanism 12 is arranged at the side edge of the correction mechanism 11 and transfers the corrected battery piece 40 to the transfer mechanism 12; the offset printing mechanism 13 is movably arranged above the transfer mechanism 12, and performs offset printing operation on the battery piece 40 arranged on the printing position of the transfer mechanism 12; the glue spot detecting mechanism 14 is arranged at the side edge of the glue spot printing mechanism 13 and is used for detecting glue spots of the glue spot finished battery piece 40 arranged on the glue spot detecting mechanism; the battery piece 40 with OK detection is transferred to the second side printing detection assembly 30 through the turnover assembly 20 to perform dispensing detection operation; the NG-detecting battery piece 40 is transferred into the NG magazine by a robot arm.

Referring to fig. 1 and 2, in the present embodiment, the correction mechanism 11 includes a support table 111, a movable plate 112, a lateral movement correction device 113, and a longitudinal movement correction device 114; the support base 111 is a support body; the movable plate 112 is movably arranged on the supporting table 111; the lateral motion correction device 113 and the longitudinal motion correction device 114 are respectively arranged on the supporting table 111 and respectively connected with the movable plate 112 in a transmission way, so that fine adjustment in the lateral direction and the longitudinal direction of the battery piece 40 arranged on the movable plate 112 is respectively realized, and the battery piece 40 is positioned at a correct position. Specifically, the movable plate 112 is provided with at least one first slot 1121, and the transfer mechanism 12 can movably extend into the at least one first slot 1121, so as to perform a transfer operation on the adjusted battery piece 40; the lateral motion correction device 113 and the longitudinal motion correction device 114 are both of the prior art, so specific correction processes and models thereof are not described herein, as long as the present application is satisfied.

Referring to fig. 1 and 3, in the present embodiment, the transfer mechanism 12 includes a printing platform 121, a fork carriage assembly 122, and a translation plate assembly 123; the printing platform 121 is fixedly arranged at the side edge of the correcting mechanism 11; the fork support carrying assembly 122 and the translation plate assembly 123 are respectively and movably arranged on the printing platform 121, and the fork support carrying assembly 122 transfers the battery piece 40 on the correction mechanism 11 to a printing position below the offset printing mechanism 13 for offset printing operation; the translating plate assembly 123 transfers the printed battery sheet 40 to the spot-detecting mechanism 14.

Referring to fig. 3 and 4, in the present embodiment, the fork carriage assembly 122 includes a mounting frame 1221, a traversing device 1222, a transfer table 1223, and a lifting device 1224; the mounting rack 1221 is fixedly arranged on the printing platform 121; the traversing device 1222 is disposed on the mount 1221; the transfer table 1223 is movably disposed on the mounting frame 1221 and is in transmission connection with the traversing motion device 1222, and the traversing motion device 1222 drives the transfer table 1223 to make a transverse motion on the mounting frame 1221, so as to transfer the battery piece 40 on the correction mechanism 11 to a printing position below the offset printing mechanism 13; the lifting device 1224 is disposed on the mounting frame 1221 and connected to the transfer table 1223, and drives the transfer table 1223 to perform lifting motion. Specifically, the mounting rack 1221 is provided with a sliding rail 1221, and the transfer table 1223 is movably disposed on the sliding rail 1221; the traversing device 1222 and the lifting device 1224 are related art, so specific structures thereof are not described herein, as long as the present application is satisfied; a plurality of vacuum adsorption nozzles 12231 are respectively arranged at two ends of the transfer table 1223, and the battery piece 40 is adsorbed by the plurality of vacuum adsorption nozzles 12231, so as to fix the battery piece 40; the translating plate assembly 123 is also a prior art, so the specific structure thereof is not described herein, as long as the present application is satisfied.

Referring to fig. 1 and 5, in the present embodiment, the offset printing mechanism 13 includes a lifting assembly 131, a printing screen 132, a first lateral movement assembly 133, a doctor lifting assembly 134, and a printing doctor assembly 135; the lifting assembly 131 is arranged at the side edge of the printing platform 121; the printing screen 132 is arranged on the lifting assembly 131, and the lifting assembly 131 drives the printing screen 132 to do linear lifting motion; the first transverse movement assembly 133 is movably arranged on the printing screen 132; the scraper lifting assembly 134 is movably arranged on the first transverse movement assembly 133, and the first transverse movement assembly 133 drives the scraper lifting assembly 134 to transversely move; the printing scraper assembly 135 is disposed below the scraper lifting assembly 134 and can be in contact connection with the printing screen 132, and the first transverse movement assembly 133 and the scraper lifting assembly 134 cooperate to drive the printing scraper assembly 135 to move, so that the printing screen 132 cooperates to realize offset printing operation. Specifically, the lifting assembly 131, the printing screen 132, the first lateral movement assembly 133, the doctor lifting assembly 134, and the printing doctor assembly 135 are all related art, so specific structures thereof are not described herein, as long as the present application is satisfied; the printing screen 132 is provided with two printing chambers 1321, and the printing chambers 1321 are provided with a plurality of glue holes in a penetrating manner, and the positions of the glue holes respectively correspond to the positions of the corresponding glue dispensing positions on the battery piece 40.

Referring to fig. 1 and 6, in the present embodiment, the spot detecting mechanism 14 includes a detecting platform 141, a fixing frame 142 and a photographing detecting assembly 143; the detection platform 141 is fixedly arranged at one side of the transfer mechanism 12, and the translation plate assembly 123 transfers the battery piece 40 after the printing of the upper-position offset printing of the printing platform 121 to the detection platform 141; the fixing frame 142 is fixedly arranged at the side edge of the detection platform 141; the photographing detection assembly 143 is fixedly arranged on the fixing frame 142 and right above the detection platform 141, and performs a glue spot detection operation on the battery piece 40 after finishing the glue spot printing on the detection platform 141. Specifically, at least one second groove 1411 is penetrating and arranged on the detection platform 141, and the turnover component 20 can be movably arranged in at least one second groove 1411; the photographing detection assembly 143 is of the prior art, so specific structures thereof are not described herein, as long as the present application is satisfied.

Referring to fig. 1 and 7, in the present embodiment, the turnover assembly 20 includes a support frame 21, a turnover power assembly 22, a rotation shaft 23, and at least one turnover rod 24; the supporting frame 21 is fixedly arranged on the side edge of the glue point detection mechanism 14; the overturning power assembly 22 is arranged on the supporting frame 21; the rotating shaft 23 is movably arranged on the supporting frame 21 and is in transmission connection with the overturning power assembly 22; at least one turnover rod 24 is fixedly arranged on the rotating shaft 23 and moves along with the movement of the rotating shaft 23; specifically, the roll-over power assembly 22 includes a rotary motor 221 and a decelerator 222; the decelerator 222 is disposed on the support frame 21, and is in driving connection with the rotating motor 221 and the rotating shaft 23, respectively.

Referring to fig. 1, in the present embodiment, the structure of the second side printing detection assembly 30 is similar to that of the first side printing detection assembly 10, so that the specific structure and operation thereof will not be described herein.

The utility model relates to a production device for a battery piece, which comprises the glue dot printing detection mechanism.

It should be noted that the working process of the glue point printing detection mechanism and the production device for the battery piece provided by the utility model is as follows: the battery piece 40 is placed on the correction mechanism 11 of the first surface printing detection assembly 10 by a mechanical arm or manually to perform correction operation; the corrected battery piece 40 is transported to a printing position on the printing platform 121 through the fork support carrying assembly 122; then the lifting component 131 drives the printing screen 132 to move downwards to contact with the battery piece 40 in the printing position, and then the first transverse movement component 133 and the scraper lifting component 134 cooperate to drive the printing scraper component 135 to move, so that the first transverse movement component cooperates with the printing screen 132 to perform offset printing operation on the battery piece 40 in the printing position; the translation board assembly 123 transfers the battery piece 40 after the offset printing is completed to the detection platform 141, the photographing detection assembly 143 performs glue spot detection on the battery piece 40 set on the detection platform 141, and the battery piece 40 for detecting OK is transferred to the second face printing detection assembly 30 through the turnover assembly 20 to perform glue spot detection operation.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (10)

1. The glue point printing detection mechanism for the battery piece is characterized by comprising a first surface printing detection assembly and a second surface printing detection assembly, and a turnover assembly movably arranged between the first surface printing detection assembly and the second surface printing detection assembly; the first surface printing detection assembly and the second surface printing detection assembly comprise a correction mechanism, a transfer mechanism and a glue point detection mechanism which are sequentially arranged; the offset printing mechanism is movably arranged above the transfer mechanism; the correction mechanism performs correction operation on the battery piece arranged on the correction mechanism; the transfer mechanism transfers the corrected battery piece to a printing position of the transfer mechanism, and transfers the printed battery piece to the glue point detection mechanism; the offset printing mechanism performs offset printing operation on the battery piece arranged on the printing position of the transfer mechanism; the glue point detection mechanism carries out glue point detection operation on the battery piece arranged on the glue point detection mechanism.

2. The paste spot printing detection mechanism for a battery cell according to claim 1, wherein the correction mechanism comprises a support table, a movable plate, a lateral movement correction device and a longitudinal movement correction device; the supporting table is a supporting main body; the movable plate is movably arranged on the supporting table; the transverse motion correcting device and the longitudinal motion correcting device are respectively arranged on the supporting table and are respectively connected with the movable plate in a transmission way.

3. The glue dot printing detection mechanism for a battery sheet of claim 1, wherein the transfer mechanism comprises a printing platform, a fork carriage assembly, and a translating plate assembly; the printing platform is fixedly arranged on the side edge of the correcting mechanism; the fork support carrying assembly and the translation plate assembly are respectively and movably arranged on the printing platform.

4. The glue dot printing detection mechanism for battery cells of claim 3, wherein the fork carriage assembly comprises a mounting frame, a traversing device, a transfer table and a lifting device; the mounting frame is fixedly arranged on the printing platform; the transverse moving device is arranged on the mounting frame; the transfer table is movably arranged on the mounting frame and is in transmission connection with the transverse movement device; the lifting movement device is arranged on the mounting frame and is in transmission connection with the transfer table.

5. A spot-printing detection mechanism for a battery sheet as defined in claim 3, wherein the spot-printing mechanism comprises a lifting assembly, a printing screen, a first lateral movement assembly, a doctor lifting assembly, and a printing doctor assembly; the lifting component is arranged at the side edge of the printing platform; the printing screen is arranged on the lifting assembly; the first transverse movement assembly is movably arranged on the printing screen; the scraper lifting assembly is movably arranged on the first transverse movement assembly; the printing scraper component is arranged below the scraper lifting component and can be in contact connection with the printing screen, and the first transverse movement component and the scraper lifting component are matched to drive the printing scraper component to move.

6. The glue dot printing detection mechanism for the battery piece according to claim 5, wherein two printing cavities are arranged on the printing screen, a plurality of glue holes are formed in the printing cavities in a penetrating mode, and the positions of the glue holes correspond to the positions of corresponding glue dot positions on the battery piece respectively.

7. The glue dot printing detection mechanism for the battery piece according to claim 1, wherein the glue dot detection mechanism comprises a detection platform, a fixing frame and a photographing detection assembly; the detection platform is fixedly arranged on one side of the transfer mechanism; the fixing frame is fixedly arranged on the side edge of the detection platform; the photographing detection assembly is fixedly arranged on the fixing frame and is arranged right above the detection platform.

8. The glue dot printing detection mechanism for a battery piece according to claim 1, wherein the turnover assembly comprises a support frame, a turnover power assembly, a rotating shaft and at least one turnover rod; the support frame is fixedly arranged on the side edge of the glue point detection mechanism in the first surface printing detection assembly; the overturning power assembly is arranged on the supporting frame; the rotating shaft is movably arranged on the supporting frame and is in transmission connection with the overturning power component; at least one overturning rod is fixedly arranged on the rotating shaft.

9. The spot-on-paste printing detection mechanism for a battery cell according to claim 8, wherein the turnover power assembly comprises a rotary motor and a decelerator; the speed reducer is arranged on the supporting frame and is respectively in transmission connection with the rotating motor and the rotating shaft.

10. A production apparatus for a battery sheet, characterized by comprising the offset printing detection mechanism according to any one of claims 1 to 9.