CN216862089U - Battery surface nanoimprint film tearing mechanism - Google Patents

Abstract

The utility model provides a battery surface nanoimprint film tearing mechanism which comprises a film tearing X-axis driving motor, a film tearing Z-axis driving motor, an adjusting module and a film tearing module, wherein the film tearing X-axis driving motor drives the film tearing Z-axis driving motor to move along the X-axis direction, the adjusting module is in driving connection with the film tearing Z-axis driving motor along the Y-axis direction, and the film tearing module is movably connected with the adjusting module. According to the automatic film tearing device, the automatic film tearing operation of the film paper is realized by arranging the film tearing X-axis driving motor, the film tearing Z-axis driving motor, the adjusting module and the film tearing module, compared with the traditional manual film tearing, the automatic film tearing device is short in time consumption and high in film tearing efficiency, the production efficiency is greatly improved, and the large-scale production is facilitated.

Description

Battery surface nanoimprint film tearing mechanism

Technical Field

The utility model relates to the technical field of film tearing, in particular to a battery surface nanoimprint film tearing mechanism.

Background

Need tear the membrane with the battery surface through the upper strata from type paper after the nanoimprint printing in the battery processing production and handle, most tear the membrane process on the market and adopt the mode of artifical dyestripping to go on mostly, this mode not only need consume a large amount of manpower and materials, and the dyestripping back becomes the quality and differs, and production efficiency hangs down and leads to unable large-scale production to carry out.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a battery surface nanoimprint film tearing mechanism to solve the technical problem in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme:

the utility model provides a battery surface nanoimprint dyestripping mechanism, includes dyestripping X axle driving motor, dyestripping Z axle driving motor, adjustment module and dyestripping module, dyestripping X axle driving motor drive dyestripping Z axle driving motor moves along X axle direction, the adjustment module is connected with dyestripping Z axle driving motor drive along Y axle direction, dyestripping module and adjustment module swing joint.

Further, the dyestripping module includes the dyestripping connecting block, rotatory paper subassembly and the double-layered membrane subassembly of inhaling, dyestripping connecting block and adjustment module swing joint, rotatory below of inhaling the paper unit mount at the dyestripping connecting block, it installs the top at the dyestripping connecting block to press from both sides the membrane unit, the output that presss from both sides the membrane unit is located the rotation and inhales paper subassembly one side, inhales paper subassembly and presss from both sides the membrane unit through the rotation and cooperatees and will treat that the dyestripping carries out the centre gripping with pressing from both sides the membrane unit.

Furthermore, the rotary paper suction assembly comprises a first rotary cylinder and a suction strip, and the first rotary cylinder drives the suction strip to rotate.

Furthermore, press from both sides the membrane subassembly and include film clamping cylinder and clamp splice, film clamping cylinder installs on the dyestripping connecting block along first revolving cylinder's installation direction, film clamping cylinder and clamp splice drive are connected.

Furthermore, the bottom of the suction strip is provided with a plurality of vacuum adsorption holes.

Further, the adjustment module includes guide rail and regulating block, the guide rail set up along Y axle direction and with dyestripping Z axle driving motor's output fixed connection, the regulating block passes through screw and guide rail swing joint, the regulating block passes through screw and dyestripping module swing joint.

Furthermore, the film tearing connecting block is of an L-shaped structure.

Compared with the prior art, the rotary paper sucking assembly and the film clamping assembly are arranged in the film tearing module and matched with each other, the rotary paper sucking assembly is used for sucking the upper film paper above the gummed paper, the film clamping assembly is used for clamping the film paper, and the film tearing module is driven to ascend through the film tearing Z axis to complete the film tearing operation; this device realizes carrying out automatic dyestripping operation to the membrane paper through setting up dyestripping X axle driving motor, dyestripping Z axle driving motor, adjustment module and dyestripping module, compares with artifical dyestripping in the past, weak point consuming time and dyestripping efficient, greatly improves production efficiency, is favorable to carrying out large-scale production.

Drawings

FIG. 1: perspective view of the present invention;

FIG. 2: top view of the utility model;

FIG. 3: the utility model is shown in the enlarged view of a in fig. 1.

Reference numerals:

51. a film tearing X-axis driving motor;

52. a film tearing Z-axis driving motor;

53. an adjusting module; 531. a guide rail; 532. an adjusting block;

54. a film tearing module; 541. a film tearing connecting block; 542. rotating the paper suction assembly; 543. a film clamping assembly;

542-1, a first rotary cylinder; 542-2, sucking strips;

543-1, a film clamping cylinder; 543-2 and a clamping block.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-2, the device includes a tearing film X-axis driving motor 51, a tearing film Z-axis driving motor 52, an adjusting module 53 and a tearing film module 54, wherein the tearing film X-axis driving motor 51 drives the tearing film Z-axis driving motor 52 to move along the X-axis direction, the adjusting module 53 is in driving connection with the tearing film Z-axis driving motor 52 along the Y-axis direction, and the tearing film module 54 is movably connected with the adjusting module 53.

Referring to fig. 3, the adjusting module 53 includes a guide rail 531 and an adjusting block 532, the guide rail 531 is disposed along the Y-axis direction and is fixedly connected to the output end of the film tearing Z-axis driving motor 52, the adjusting block 532 is movably connected to the guide rail 531 through a screw, the adjusting block 532 is movably connected to the film tearing connecting block 541 in the film tearing module 54 through a screw, and when the film tearing module is used, the position of the film tearing module 54 can be adjusted through an actually required angle, which is simple in structure and convenient and fast to operate.

Dyestripping module 54 is including dyestripping connecting block 541, the paper subassembly 542 and the double-layered membrane subassembly 543 are inhaled in the rotation, dyestripping connecting block 541 and adjustment module 53 swing joint, dyestripping connecting block 541 is L type structure, the paper subassembly 542 is installed in the below of dyestripping connecting block 541 is inhaled in the rotation, it installs the top at dyestripping connecting block 541 to press from both sides the membrane subassembly 543, the output that presss from both sides the membrane subassembly 543 is located the rotation and inhales paper subassembly 542 one side, inhale paper subassembly 542 and press from both sides the membrane subassembly 543 through the rotation and cooperate and will treat that the dyestripping paper carries out the centre gripping.

The rotary paper sucking assembly 542 comprises a first rotary cylinder 542-1 and a sucking strip 542-2, the first rotary cylinder 542-1 drives the sucking strip 542-2 to rotate, and the bottom of the sucking strip 542-2 is provided with a plurality of vacuum sucking holes for sucking the paper to be torn.

The film clamping assembly 543 comprises a film clamping cylinder 543-1 and a clamping block 543-2, the film clamping cylinder 543-1 is mounted on the film tearing connecting block 541 along the mounting direction of the first rotating cylinder 542-1, the film clamping cylinder 543-1 is in driving connection with the clamping block 543-2, when the film clamping cylinder 543-1 drives the clamping block 543-2 to approach one end of the suction strip 542-2, the film to be torn at the bottom of the suction strip 542-2 is clamped by the clamping block 543-2, and the film to be torn is matched with the film tearing Z-axis driving motor 52 to move towards the film paper disengaging direction, so that the film tearing operation is completed.

The working process is as follows: move adjustment module 53 and dyestripping module 54 to treating the dyestripping paper top through dyestripping X axle driving motor 51, inhale the strip 542-2 absorption in the paper subassembly 542 through the rotation and treat the dyestripping paper, cooperate the clamp splice 543-2 in the clamp membrane subassembly 543 will treat the dyestripping paper and carry out the centre gripping, cooperate dyestripping Z axle driving motor 52 to remove towards the dyestripping paper direction of breaking away from, accomplish the dyestripping operation.

Compared with the prior art, the rotary paper sucking assembly and the film clamping assembly are arranged in the film tearing module and matched with each other, the rotary paper sucking assembly is used for sucking the upper film paper above the gummed paper, the film clamping assembly is used for clamping the film paper, and the film tearing module is driven to ascend through the film tearing Z axis to complete the film tearing operation; this device realizes carrying out automatic dyestripping operation to the membrane paper through setting up dyestripping X axle driving motor, dyestripping Z axle driving motor, adjustment module and dyestripping module, compares with artifical dyestripping in the past, weak point consuming time and dyestripping efficient, greatly improves production efficiency, is favorable to carrying out large-scale production.

It will be evident to those skilled in the art that the utility model 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 attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model 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. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. The utility model provides a battery surface nanoimprint film tearing mechanism which characterized in that: including dyestripping X axle driving motor, dyestripping Z axle driving motor, adjustment module and dyestripping module, dyestripping X axle driving motor drive dyestripping Z axle driving motor moves along X axle direction, the adjustment module is connected with dyestripping Z axle driving motor drive along Y axle direction, dyestripping module and adjustment module swing joint.

2. The battery surface nanoimprint film tearing mechanism of claim 1, characterized in that: the dyestripping module includes the dyestripping connecting block, rotatory paper subassembly and the doubling subassembly of inhaling, dyestripping connecting block and adjustment module swing joint, rotatory below at the dyestripping connecting block of inhaling the paper unit mount, the doubling unit mount is in the top of dyestripping connecting block, the output that presss from both sides the membrane subassembly is located the rotation and inhales paper subassembly one side, inhales paper subassembly and presss from both sides the membrane subassembly through the rotation and cooperatees and will treat that the dyestripping carries out the centre gripping with the dyestripping paper.

3. The battery surface nanoimprint film tearing mechanism of claim 2, characterized in that: the rotary paper suction assembly comprises a first rotary cylinder and a suction strip, and the first rotary cylinder drives the suction strip to rotate.

4. The battery surface nanoimprint film tearing mechanism of claim 3, characterized in that: the film clamping assembly comprises a film clamping cylinder and a clamping block, the film clamping cylinder is installed on the film tearing connecting block along the installation direction of the first rotating cylinder, and the film clamping cylinder is in driving connection with the clamping block.

5. The battery surface nanoimprint film tearing mechanism of claim 3, characterized in that: the bottom of the suction strip is provided with a plurality of vacuum adsorption holes.

6. The battery surface nanoimprint film tearing mechanism of claim 1, characterized in that: the adjusting module comprises a guide rail and an adjusting block, the guide rail is arranged along the Y-axis direction and is fixedly connected with the output end of the dyestripping Z-axis driving motor, the adjusting block is movably connected with the guide rail through a screw, and the adjusting block is movably connected with the dyestripping module through a screw.

7. The battery surface nanoimprint film tearing mechanism of claim 2, characterized in that: the film tearing connecting block is of an L-shaped structure.

Images