CN215041190U

CN215041190U - Double-printing-table double-station battery piece printing device

Info

Publication number: CN215041190U
Application number: CN202120818412.1U
Authority: CN
Inventors: 李文; 陈兵; 高阳; 朱宏; 徐英乾
Original assignee: Wuxi Aote Weixurui Technology Co ltd
Current assignee: Wuxi Aote Weixurui Technology Co ltd
Priority date: 2021-04-21
Filing date: 2021-04-21
Publication date: 2021-12-07
Anticipated expiration: 2031-04-21

Abstract

The utility model provides a two seal station duplex position battery piece printing device, it includes that battery piece input mechanism, printing bear mechanism, first printing mechanism, second printing mechanism and battery piece output mechanism. The utility model provides a two seal station duplex position battery piece printing device, it is provided with two printing stations and two mobilizable printing stations. The two printing tables alternately acquire the electric battery pieces to be printed input by the battery piece input mechanism from the battery piece feeding and discharging station, and translate the battery pieces to be printed to the corresponding printing station to perform printing operation, and the battery piece output mechanism is used for picking up the printed battery pieces from the printing tables and outputting the battery pieces. Compare with traditional battery piece printing device, the utility model discloses battery piece printing efficiency has been promoted remarkably.

Description

Double-printing-table double-station battery piece printing device

Technical Field

The utility model belongs to the technical field of battery production and specifically relates to a two seal station duplex position battery piece printing device.

Background

During the production process of the battery assembly, a conductive material is printed on the surface of the battery piece to form grid lines for collecting current. At present, the printing of the grid line is generally completed by adopting a screen printing process. The existing screen printing equipment is only provided with one printing table and one printing station, and the printing efficiency is low.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a two seal station duplex position battery piece printing device, it adopts following technical scheme:

the utility model provides a two seal station duplex position battery piece printing device, includes that battery piece input mechanism, printing bear the weight of the mechanism, first printing mechanism, second printing mechanism and battery piece output mechanism, wherein:

the battery piece input mechanism and the battery piece output mechanism are arranged on a first horizontal axis, a battery piece feeding and discharging station is formed between the battery piece input mechanism and the battery piece output mechanism, a first printing station and a second printing station are respectively arranged on two sides of the battery piece feeding and discharging station, and the first printing station, the battery piece feeding and discharging station and the second printing station are positioned on a second horizontal axis perpendicular to the first horizontal axis;

the printing bearing mechanism comprises a translation mechanism, and a first printing table and a second printing table which are connected to the translation mechanism, wherein the translation mechanism is used for driving the first printing table and the second printing table to translate on a second horizontal axis so as to realize position switching of the first printing table between the first printing station and the battery piece feeding and discharging station and the second printing table between the second printing station and the battery piece feeding and discharging station;

the first printing mechanism is arranged at the first printing station, and the second printing mechanism is arranged at the second printing station;

the battery piece input mechanism conveys the battery pieces to be printed to a first printing table or a second printing table which is positioned at the charging and discharging station of the battery pieces, the first printing mechanism and the second printing mechanism respectively perform printing on the battery pieces to be printed which are positioned at the first printing station and the second printing station, and the battery piece output mechanism outputs the battery pieces which are positioned at the charging and discharging station of the battery and are printed.

The utility model provides a two seal station duplex position battery piece printing device, it is provided with two printing stations and two mobilizable printing stations. The two printing tables alternately obtain the battery pieces to be printed from the battery piece feeding and discharging stations and translate the battery pieces to be printed to the corresponding printing stations to perform printing operation. Compare with traditional battery piece printing device, the utility model discloses battery piece printing efficiency has been promoted remarkably.

In some embodiments, the first and second printing tables are coupled to a same drive end of the translation mechanism, and the second printing table is synchronously translated by the same drive end of the translation mechanism. The distance between the first printing table and the second printing table, the distance between the first printing station and the battery piece feeding and discharging station, and the distance between the second printing station and the battery piece feeding and discharging station are equal. When the first printing table is translated to the feeding and discharging station of the battery piece, the second printing table is synchronously translated to the second printing station, and when the second printing table is translated to the feeding and discharging station of the battery piece, the first printing table is synchronously translated to the first printing station.

Through setting up the interval between first printing platform and the second printing platform, the interval between first printing station and the unloading station of battery piece, the interval between second printing station and the unloading station of battery piece to equal, translation mechanism only needs to set up a drive end and can realize the synchronous drive to first printing platform and second printing platform to realize first printing platform, second printing platform in the printing station that corresponds separately and go up the alternate movement between the unloading station.

In some embodiments, the first print station is coupled to a first drive end of the translation mechanism and the second print station is coupled to a second drive end of the translation mechanism. When the first printing table is driven by the first driving end to move to the battery piece feeding and discharging station, the second printing table is driven by the second driving end to move to the second printing station, and when the first printing table is driven by the first driving end to move to the first printing station, the second printing table is driven by the second driving end to move to the battery piece feeding and discharging station.

The first printing table and the second printing table are respectively connected to different driving ends of the translation mechanism, and under the driving of the respective driving ends, the space between the first printing table and the second printing table, the space between the first printing station and the battery piece feeding and discharging station, and the space between the second printing station and the battery piece feeding and discharging station do not need to be set in any adaptability, so that the first printing table and the second printing table can alternately move between the corresponding printing stations and the feeding and discharging stations.

In some embodiments, the first and second printing stations each comprise a mounting plate, a rotary drive, and a bearing table, wherein: the mounting plate is connected to the translation mechanism; the rotary driving piece is arranged on the mounting plate; the plummer is connected on rotary driving piece's drive end, and rotary driving piece is used for driving the plummer to rotate in order to realize the horizontal angle adjustment to bearing the battery piece on the plummer.

Through setting the printing platform into mounting plate, rotary driving piece and plummer, realized having guaranteed the printing effect to the horizontal angle adjustment of treating printing battery piece of bearing on the printing platform.

In some embodiments, the first printing table and the second printing table further comprise a battery piece translation mechanism arranged on the bearing table, and the battery piece translation mechanism is matched with the battery piece input mechanism and receives a battery piece to be printed from the battery piece input mechanism; and the battery piece translation mechanism is matched with the battery piece output mechanism to output the loaded battery piece which is printed to the battery piece output mechanism.

The printing table is provided with a battery piece translation mechanism capable of driving the battery piece to translate towards the battery piece output mechanism, and in the battery piece feeding stage, the battery piece to be printed input from the battery piece input mechanism can be smoothly transited to the printing table under the driving of the battery piece translation mechanism. And in the battery piece blanking stage, the printed battery piece can be smoothly transited to the battery piece output structure under the driving of the battery piece translation mechanism.

In some embodiments, the cell translation mechanism includes a paper releasing roller, a paper receiving roller, a paper rolling and driving mechanism, wherein: the paper discharge roller is arranged at the first end of the bearing table close to the battery piece input mechanism; the delivery roller is arranged at the second end of the bearing table close to the battery piece output mechanism. The roll paper is arranged on the paper releasing roller, and the roll paper bypasses the table board of the bearing table after being released by the paper releasing roller and moves close to the table board of the bearing table to be wound on the paper collecting roller. The driving mechanism is used for driving the paper releasing roller and the paper collecting roller to rotate so as to drive the roll paper to move.

The utility model provides a concrete battery piece translation mechanism, it is through putting paper running roller, delivery running roller, stock form and actuating mechanism's cooperation, drives the battery piece and removes on the mesa of printing platform.

In some embodiments, the cell translation mechanism further comprises a roll paper tensioning mechanism arranged on the bearing platform, and the roll paper discharged from the paper discharge roller is tensioned by the roll paper tensioning mechanism and then wound onto the paper collection roller.

Tensioning to the stock form has been realized through setting up stock form straining device for the stock form hugs closely on the mesa of plummer with the tensioning state all the time, prevents to produce the influence to transporting the battery piece.

In some embodiments, the table top of the carrier table is provided with an adsorption hole, and the adsorption hole absorbs the battery piece carried on the carrier table through the roll paper.

Through setting up the absorption hole, realized the absorption location to bearing in the battery piece on the plummer, prevented that the battery piece from sliding to guarantee battery piece adjustment accuracy and prevent that the battery piece from landing when carrying.

In some embodiments, the double-printing-table double-station battery piece printing device further comprises a first detection mechanism arranged above the battery piece feeding and discharging station and a second detection mechanism arranged above the battery piece output mechanism, wherein: the first detection mechanism is used for detecting the position information of the battery piece to be printed at the battery piece feeding and discharging station; the second detection mechanism is used for detecting whether the printed battery piece on the battery piece output mechanism is qualified or not.

Through setting up first detection mechanism, realized treating the detection of the positional information of printing battery piece, the printing platform can implement the horizontal angle adjustment to the battery piece fast based on this positional information. And by arranging the second detection mechanism, the printing quality detection of the printed battery piece is realized.

Drawings

Fig. 1 is a schematic structural view of a double-station battery cell printing device with two printing stations according to an embodiment of the present invention at a first viewing angle;

fig. 2 is a schematic structural view of a double-station battery cell printing device with two printing stations according to an embodiment of the present invention at a second viewing angle;

fig. 3 is a schematic structural view of a double-station battery cell printing device with two printing stations according to an embodiment of the present invention at a third viewing angle;

fig. 4 is a schematic view of an assembly structure of the translation mechanism and the printing table in the embodiment of the present invention;

fig. 5 is a schematic structural view of a printing table of a printing support mechanism in an embodiment of the present invention;

fig. 6 is a schematic view of a printing process of a double-station battery piece printing device provided by an embodiment of the present invention;

fig. 1 to 6 include: the device comprises a battery piece input mechanism 10, a printing bearing mechanism 20, a first printing mechanism 30, a second printing mechanism 40, a battery piece output mechanism 50, a translation mechanism 21, a first printing table 22, a second printing table 23, a mounting plate 221, a rotary driving piece 222, a bearing table 223, a paper releasing roller 224, a paper collecting roller 225, a paper winding 226, a driving mechanism 227 and a paper winding tensioning mechanism 228.

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description.

The existing screen printing equipment is only provided with one printing table and one printing station, and the printing efficiency is low. In view of this, the utility model provides a double-printing-table and double-station battery piece printing device,

the existing screen printing equipment is only provided with one printing table and one printing station, and the printing efficiency is low. In view of this, the utility model provides a two seal station duplex position battery piece printing device is in order to promote battery piece printing efficiency.

As shown in fig. 1 to fig. 3, the embodiment of the present invention provides a double-station battery piece printing apparatus, which includes a battery piece input mechanism 10, a printing support mechanism 20, a first printing mechanism 30, a second printing mechanism 40, and a battery piece output mechanism 50. Wherein:

the battery piece input mechanism 10 and the battery piece output mechanism 50 are arranged on a first horizontal axis X, a battery piece feeding and discharging station A is formed between the battery piece input mechanism 10 and the battery piece output mechanism 50, a first printing station B and a second printing station C are arranged on two sides of the battery piece feeding and discharging station A respectively, and the first printing station B, the battery piece feeding and discharging station A and the second printing station C are located on a second horizontal axis Y perpendicular to the first horizontal axis X.

The printing bearing mechanism 20 comprises a translation mechanism 21, and a first printing table 22 and a second printing table 23 which are connected to the translation mechanism 21, wherein the translation mechanism 21 is used for driving the first printing table 22 and the second printing table 23 to translate along a second horizontal axis Y so as to realize the position switching of the first printing table 22 between the first printing station B and the battery piece loading and unloading station A and the position switching of the second printing table 23 between the second printing station C and the battery piece loading and unloading station A.

The first printing mechanism 30 is provided at the first printing station B, and the second printing mechanism 40 is provided at the second printing station C.

The cell input mechanism 10 conveys the cells to be printed to the first printing table 22 or the second printing table 23 located at the cell loading and unloading station a, the first printing mechanism 30 and the second printing mechanism 40 respectively print the cells to be printed at the first printing station B and the second printing station C, and the cell output mechanism 50 outputs the printed cells located at the cell loading and unloading station a.

It is visible, the utility model provides a two seal station duplex position battery piece printing device, through setting up two printing stations and two mobilizable printing stations, two printing stations acquire from the unloading station department on the battery piece in turn and wait to print the battery piece and will wait to print the battery piece translation and to locate to implement the printing operation to the printing station that corresponds to battery piece printing efficiency has been promoted.

In some alternative embodiments, the first printing table 22 and the second printing table 23 are connected to the same driving end of the translation mechanism 21, and the first printing table 22 and the second printing table 23 are synchronously translated by the same driving end of the translation mechanism 21. For example, optionally, the translation mechanism 21 includes a translation guide rail, a sliding block and a lead screw driving motor, the sliding block is slidably connected to the translation guide rail and is connected to the driving rod of the lead screw driving motor, the first printing table 22 and the second printing table 23 are both installed on the sliding block, and the lead screw driving motor drives the sliding block to translate along the translation guide rail, so as to drive the first printing table 22 and the second printing table 23 to translate synchronously.

Particularly, the distance between the first printing table 22 and the second printing table 23, the distance between the first printing station B and the battery piece loading and unloading station a, and the distance between the second printing station C and the battery piece loading and unloading station a are all equal. With such arrangement, under the driving of the translation mechanism 21, when the first printing table 22 translates to the battery piece loading and unloading station a, the second printing table 23 synchronously translates to the second printing station C; when the second printing table 23 is translated to the battery piece loading and unloading station a, the first printing table 22 is synchronously translated to the first printing station B. Namely, when one printing platform translates to the battery piece feeding and discharging station A to perform blanking on the battery piece, the other printing platform carries the battery piece to translate synchronously to the printing station corresponding to the printing platform to receive printing operation.

In other alternative embodiments, the first printing table 22 is connected to a first driving end of the translation mechanism 21, and the second printing table 23 is connected to a second driving end of the translation mechanism 21, and the first driving end and the second driving end respectively and independently drive the first printing table 22 and the second printing table 23 to translate. If optionally, the translation mechanism 21 includes a translation guide rail, a first sliding block, a second sliding block, a first lead screw motor and a second lead screw motor, the first sliding block and the second sliding block are both connected to the translation guide rail in a sliding manner and are respectively connected to the driving rods of the first lead screw motor and the second lead screw motor, the first printing table 22 and the second printing table 23 are respectively installed on the first sliding block and the second sliding block, and the first lead screw motor and the second lead screw motor respectively and independently drive the first sliding block and the second sliding block to translate, so as to drive the first printing table 22 and the second printing table 23 to translate. In order to align the battery piece with the printing mechanism, the translation mechanism 21 may also adjust the position of the printing table carrying the battery piece to be printed along the second horizontal axis Y, i.e. adjust the position of the battery piece to be printed along the second horizontal axis Y. When the adjustment is finished, another printing station may not be precisely butted with the cell input mechanism 10 and the cell output mechanism 50, but such an error is still within a reasonable range, which does not affect the feeding and discharging of the cells, nor the accuracy of the subsequent printing.

In the printing process, when the first driving end drives the first printing table 22 to move to the cell loading and unloading station A, the second driving end drives the second printing table 23 to move to the second printing station C; and when the first driving end drives the first printing table 22 to move to the first printing station B, the second driving end drives the second printing table 23 to move to the battery piece loading and unloading station a. Namely, when one of the printing tables is translated to the battery piece feeding and discharging station A to perform feeding and discharging on the battery pieces, the other printing table carries the battery pieces to be synchronously translated to the corresponding printing station to receive printing operation. And when at least one of a certain printing table moving on one side of the first horizontal axis X and a printing mechanism corresponding to the printing table has a problem and needs to be overhauled, the printing table can be stopped, and at the moment, the other printing mechanism and the corresponding printing table can continue to carry out loading, printing and unloading work without being influenced, so that the equipment still keeps a certain capacity. The problem may be, among others, changing screens or scrapers, wiping screens, adding printing paste, mechanically adjusting the printing table, etc.

In these embodiments, since the first printing table 22 and the second printing table 23 are respectively connected to different driving ends of the translation mechanism 21, the first printing table 22 and the second printing table 23 can be alternatively moved between the corresponding printing stations and the corresponding loading and unloading stations without any adaptive setting on the distance between the first printing table 22 and the second printing table 23, the distance between the first printing station B and the cell loading and unloading station a, and the distance between the second printing station C and the cell loading and unloading station a. Obviously, the two printing stations can ensure that the whole process is accurately butted with the cell input mechanism 10 and the cell output mechanism 50 to carry out charging and discharging on the cell, and the two printing stations respectively carry out printing alignment along the second horizontal axis Y with the corresponding printing mechanisms, and the two printing stations are not affected by each other.

As is well known to those skilled in the art, in order to ensure the printing accuracy of the grid lines, the horizontal angle adjustment of the battery piece needs to be performed before the battery piece is printed. With this in mind, optionally, as shown in fig. 4, the first printing station 22 and the second printing station 23 each comprise a mounting plate 221, a rotary drive 222, and a bearing table 223, wherein: the mounting plate 221 is connected to the translation mechanism 21; the rotary drive 222 is disposed on the mounting plate 221; the carrying platform 223 is connected to a driving end of the rotary driving member 222, and the rotary driving member 222 is used for driving the carrying platform 223 to rotate so as to adjust the horizontal angle of the battery piece carried on the carrying platform 223.

The rotary driving part has higher rotational positioning precision, and the rotary driving part is used as a driving bearing platform to rotate, so that the horizontal angle of the bearing platform can be accurately adjusted. In this embodiment, the rotary driving element 222 is a DD motor, and alternatively, the rotary driving element 222 may also be a driving device such as a servo motor or an electric index plate, and when a driving device other than the DD motor is used, the mounting position of the driving device may be adaptively changed, and the accurate adjustment of the horizontal angle of the plummer may also be achieved.

Optionally, as shown in fig. 5, the first printing table 22 and the second printing table 23 further include a battery piece translation mechanism disposed on the carrying table 223, the battery piece translation mechanism is matched with the battery piece input mechanism 10 to receive a battery piece to be printed from the battery piece input mechanism 10, and the battery piece translation mechanism is matched with the battery piece output mechanism 50 to output the carried battery piece after printing to the battery piece output mechanism 50. That is, during the process of feeding the battery pieces, the battery pieces to be printed input from the battery piece input mechanism 10 can be smoothly transferred to the printing table under the driving of the battery piece translation mechanism. In the process of blanking the battery piece, the printed battery piece can be smoothly transited to the battery piece output structure 50 under the driving of the battery piece translation mechanism.

With continued reference to fig. 5, optionally, the cell translation mechanism includes a paper discharge roller 224, a paper delivery roller 225, a paper roll 226, and a drive mechanism 227, wherein: the paper feeding roller 224 is disposed at a first end of the loading platform 223 near the battery piece input mechanism 10. The delivery roller 225 is disposed at a second end of the support base 223 adjacent to the battery sheet output mechanism 50. The roll paper 226 is mounted on the paper discharge roller 224, and the roll paper 226 is discharged by the paper discharge roller 224, passes around the top surface of the support table 223, and moves close to the top surface of the support table 223 to be wound around the paper delivery roller 225, that is, the roll paper 226 moves from the first end of the support table 223 close to the top surface of the support table 223 toward the second end of the support table 223. The driving mechanism 227 is used for driving the paper releasing roller 224 and the paper collecting roller 225 to rotate, so as to drive the roll paper to move.

The working process of the cell translation mechanism is as follows:

in the battery piece feeding process, the battery piece to be printed is driven by the battery piece input mechanism 10 to move towards the first printing table 22 or the second printing table 23 located at the battery piece feeding and discharging station a, when the front end edge of the battery piece to be printed moves to the table top of the bearing table 223, the driving mechanism 227 drives the paper releasing roller 224 and the paper collecting roller 225 to rotate so as to drive the roll paper 226 tightly attached to the table top of the bearing table 223 to move, and the battery piece to be printed continues to move forwards under the drive of the roll paper 226 until the battery piece to be printed is completely borne on the table top of the bearing table 223.

In the battery piece blanking process, when the first printing table 22 or the second printing table 23 carries the printed battery piece to move to the battery piece loading and unloading station a, the driving mechanism 227 drives the paper releasing roller 224 and the paper receiving roller 225 to rotate so as to drive the roll paper 226 tightly attached to the table top of the bearing table 223 to move, and the printed battery piece moves towards the battery piece output structure 50 under the driving of the roll paper 226 until the printed battery piece completely moves to the battery piece output structure 50.

Optionally, as shown in fig. 5, the battery sheet translation mechanism further includes a roll paper tensioning mechanism 228 disposed on the carrier 223, and the roll paper 226 discharged from the paper discharge roller 224 is tensioned by the roll paper tensioning mechanism 228 and then wound onto the paper delivery roller 225. That is, by providing the roll paper tension mechanism 228, the roll paper 226 is always kept in a tensioned state and closely attached to the surface of the platform 223, and the roll paper is prevented from being warped and arched, thereby ensuring the effect of conveying the cell sheet by the roll paper 226. In some alternative implementations, web tensioning mechanism 228 includes a telescoping arm having a first end attached to carrier 223 and a tensioning wheel mounted at a second end of the telescoping arm and abutting against an inner side of web 226, the tensioning wheel remaining in constant abutment against web 226 under the telescoping actuation of the telescoping arm, thereby allowing web 226 to be continuously tensioned.

Optionally, the mesa of plummer 223 is provided with the absorption hole, and the absorption hole sees through the stock form 226 and adsorbs the battery piece of bearing on plummer 223 to the realization prevents that the battery piece from sliding to the absorption location of battery piece, thereby guarantees battery piece adjustment accuracy and prevents that the battery piece from landing when carrying.

Optionally, the embodiment of the utility model provides a two-print-table duplex position battery piece printing device is still including setting up the first detection mechanism and the second detection mechanism of setting in the 50 tops of battery piece output mechanism of unloading station A top on the battery piece, wherein: the first detection mechanism is used for detecting the position information of the battery piece to be printed at the battery piece feeding and discharging station A. The second detection mechanism is used for detecting the printing quality of the printed battery piece on the battery piece output mechanism 50, judging whether the printed battery piece is qualified or not, and feeding the result back to the control system.

Optionally, after the battery piece to be printed is conveyed to the bearing table 223 of the first printing table 22 or the second printing table 23 located at the battery piece loading and unloading station a, the first detection mechanism obtains the position information of the battery piece to be printed through detection modes such as photographing and sends the detected position information to the control system, the control system analyzes and determines the adjustment amount and generates an adjustment command based on the position information of the battery piece to be printed, and the rotary driving member 222 drives the bearing table 223 to rotate by a predetermined angle based on the adjustment command, so that the horizontal angle adjustment of the battery piece to be printed is realized.

In order to make the working process of the dual-station battery piece printing device provided by the present invention more clear to those skilled in the art, the following description will be made in detail with reference to fig. 6 for the printing process of the dual-station battery piece printing device provided by the present invention in a specific application example.

As shown in fig. 6(a), at a first time, the first printing table 22 is located at the first printing station B, and the printed battery pieces thereon are subjected to the printing operation of the first printing mechanism 30; the second printing table 23 is located at the loading and unloading station a to receive the battery piece to be printed input by the battery piece input mechanism 10, and the first detection mechanism performs position detection and feedback on the battery piece to be printed.

As shown in fig. 6(b), at the second time, under the driving of the translation mechanism 21, the first printing table 22 carries the printed battery piece to move to the battery piece loading and unloading station a; the second printing table 23 carries the battery piece to be printed to the second printing station C to wait for printing.

As shown in fig. 6(c), at the third time, the first printing station 22 discharges the printed battery piece to the battery piece output mechanism 50 and receives a new battery piece to be printed from the battery piece input mechanism 10, the second detection mechanism performs discharge detection and analysis on the printed battery piece, and the result is fed back to the control system; the battery plate on the second printing table 23 is subjected to the printing operation of the second printing mechanism 40.

As shown in fig. 6(d), at the fourth time, under the driving of the translation mechanism 21, the first printing table 22 carries the battery piece to be printed to move to the first printing station B to wait for printing; the second printing table 23 carries the printed battery plate to move to the battery plate loading and unloading station a.

As shown in fig. 6(e), at a fifth time, the battery piece on the first printing table 22 is subjected to the printing operation by the first printing mechanism 30; the second printing station 23 discharges the printed battery piece to the battery piece output mechanism 50 and receives a new battery piece to be printed from the battery piece input mechanism 10. And in the fifth time, the double-printing-table double-station battery piece printing device returns to the working state of the first time, and a new cycle of circular printing process is started.

Optionally, the device provided by the application can also use conductive adhesive materials as printing ink, and accordingly, the two printing mechanisms can glue the preset positions of the battery pieces, so that subsequent lamination curing treatment is facilitated, and the laminated battery string is finally formed.

The invention has been described above with a certain degree of particularity and detail. It will be understood by those of ordinary skill in the art that the description of the embodiments is merely exemplary and that all changes that may be made without departing from the true spirit and scope of the present invention are intended to be within the scope of the present invention. The scope of the invention is defined by the appended claims rather than by the foregoing description of the embodiments. Moreover, the embodiments mentioned in the present application are not only implemented individually, but also some embodiments may be implemented in combination.

Claims

1. The utility model provides a two ink pad duplex position battery piece printing device, its characterized in that, two ink pad duplex position battery piece printing device includes that battery piece input mechanism, printing bear mechanism, first printing mechanism, second printing mechanism and battery piece output mechanism, wherein:

the battery piece feeding mechanism and the battery piece output mechanism are arranged on a first horizontal axis, a battery piece feeding and discharging station is formed between the battery piece feeding mechanism and the battery piece output mechanism, a first printing station and a second printing station are respectively arranged on two sides of the battery piece feeding and discharging station, and the first printing station, the battery piece feeding and discharging station and the second printing station are positioned on a second horizontal axis perpendicular to the first horizontal axis;

the printing bearing mechanism comprises a translation mechanism, and a first printing table and a second printing table which are connected to the translation mechanism, wherein the translation mechanism is used for driving the first printing table and the second printing table to translate on a second horizontal axis so as to realize the position switching of the first printing table between the first printing station and the battery piece feeding and discharging station and the position switching of the second printing table between the second printing station and the battery piece feeding and discharging station;

the battery piece input mechanism conveys the battery pieces to be printed to the first printing table or the second printing table which is positioned at the battery piece feeding and discharging station, the first printing mechanism and the second printing mechanism respectively perform printing on the battery pieces to be printed which are positioned at the first printing station and the second printing station, and the battery piece output mechanism outputs the battery pieces which are positioned at the battery feeding and discharging station and complete the printing.

2. The double-station battery piece printing device of claim 1, wherein:

the first printing table and the second printing table are connected to the same driving end of the translation mechanism, and the first printing table and the second printing table synchronously translate under the driving of the same driving end of the translation mechanism;

the distance between the first printing table and the second printing table, the distance between the first printing station and the battery piece feeding and discharging station, and the distance between the second printing station and the battery piece feeding and discharging station are equal;

when the first printing table is translated to the battery piece feeding and discharging station, the second printing table is synchronously translated to the second printing station, and when the second printing table is translated to the battery piece feeding and discharging station, the first printing table is synchronously translated to the first printing station.

3. The double-station battery piece printing device of claim 1, wherein:

the first printing table is connected to a first driving end of the translation mechanism, and the second printing table is connected to a second driving end of the translation mechanism;

when the first printing table is driven by the first driving end to move to the battery piece loading and unloading station, the second printing table is driven by the second driving end to move to the second printing station;

when the first printing table is driven by the first driving end to move to the first printing station, the second printing table is driven by the second driving end to move to the battery piece loading and unloading station.

4. The dual-station battery piece printing device of claim 1, wherein the first printing station and the second printing station each comprise a mounting plate, a rotary drive, and a bearing table, wherein:

the mounting plate is connected to the translation mechanism;

the rotary driving piece is arranged on the mounting plate;

the plummer is connected on rotary driving spare's drive end, rotary driving spare is used for the drive the plummer rotates in order to realize bearing the weight of the horizontal angle adjustment of the battery piece on the plummer.

5. The double-printing-table double-station battery piece printing device of claim 4, wherein the first printing table and the second printing table further comprise a battery piece translation mechanism arranged on the bearing table, and the battery piece translation mechanism is matched with the battery piece input mechanism and receives a battery piece to be printed from the battery piece input mechanism; and the battery piece translation mechanism is matched with the battery piece output mechanism to output the loaded printed battery piece to the battery piece output mechanism.

6. The double-station battery piece printing device of claim 5, wherein the battery piece translation mechanism comprises a paper releasing roller, a paper collecting roller, paper rolling and driving mechanisms, wherein:

the paper discharge roller is arranged at the first end of the bearing table close to the battery piece input mechanism;

the delivery roller is arranged at the second end of the bearing table close to the battery piece output mechanism;

the roll paper is arranged on the paper releasing roller, and after being released by the paper releasing roller, the roll paper bypasses the table board of the bearing table and moves close to the table board of the bearing table to be wound on the paper collecting roller;

the driving mechanism is used for driving the paper releasing roller and the paper collecting roller to rotate so as to drive the roll paper to move.

7. The duplex station cell printing apparatus of claim 6 wherein the cell translation mechanism further comprises a roll paper tensioning mechanism disposed on the carrier, the roll paper being paid out from the payout roller being tensioned by the roll paper tensioning mechanism and then being taken up onto the delivery roller.

8. The double-printing-table double-station battery piece printing device as claimed in claim 6, wherein the table top of the bearing table is provided with adsorption holes, and the adsorption holes adsorb the battery pieces loaded on the bearing table through the roll paper.

9. The double-stamp-station double-station battery piece printing device as claimed in claim 1, further comprising a first detection mechanism disposed above the battery piece loading and unloading station and a second detection mechanism disposed above the battery piece output mechanism, wherein:

the first detection mechanism is used for detecting the position information of the battery piece to be printed at the battery piece feeding and discharging station;

and the second detection mechanism is used for detecting whether the printed battery piece on the battery piece output mechanism is qualified or not.