CN114313395A - Tectorial membrane cross cutting equipment - Google Patents

Abstract

The invention relates to the technical field of die cutting equipment, in particular to film-coating die cutting equipment which comprises a rack, wherein a material belt film material unwinding mechanism, a tensioning mechanism, a laser mark cutting mechanism, a CCD material belt detection mechanism, a chamfering die cutting mechanism, a forming mechanism, a dust removal conveying mechanism, a CCD finished product detection mechanism and a material receiving mechanism are sequentially arranged in the rack along the pole piece conveying direction; the material receiving mechanism comprises a servo motor and a main traction roller, and the servo motor is in transmission connection with the main traction roller. Compared with the prior art, through laser shear mark mechanism, one set of receiving agencies of chamfer die-cutting mechanism and forming mechanism sharing, need not to set up a plurality of drive mechanism, equipment mechanism has been simplified, the cost of whole equipment has been reduced, receiving agencies adopts servo motor intermittent type formula action to carry out the shear mark, the stability of equipment has been improved, in addition, the mode that adopts the laser shear mark carries out the shear mark to the tectorial membrane material area, need not to use the production in tectorial membrane material area that many sets of mould just can be applicable to a plurality of models, the production cost is reduced, and the work efficiency is improved.

Description

Tectorial membrane cross cutting equipment

Technical Field

The invention relates to the technical field of die cutting equipment, in particular to laminating die cutting equipment.

Background

Industrial products such as modern electronic products and the like are applied to various films more and more, and some films need to be laminated by two layers or even multiple layers and can be used only by carrying out high-precision die cutting on a laminated film.

The existing composite processing of two layers of films or multiple layers of films is mainly completed by semi-automatic equipment, some two layers of films are processed by pure hands, the semi-automatic die cutting is realized by hands for precise die cutting, the production efficiency is low, the processing quality is general, and the high-precision composite films are difficult to process.

Disclosure of Invention

The invention aims to provide laminating and die-cutting equipment with high precision aiming at the defects in the prior art.

The purpose of the invention is realized by the following technical scheme: the application provides a film-coating die-cutting device, which comprises a rack, wherein a material belt film material unwinding mechanism for unwinding a material belt and a film material is sequentially arranged in the rack along a pole piece conveying direction, a tensioning mechanism for pre-bonding the material belt and the film material to form a film-coating material belt, a laser mark cutting mechanism for cutting marks on the film-coating material belt, a CCD material belt detection mechanism for detecting the appearance of the film-coating material belt after the marks are cut, a chamfering and punching mechanism for laminating the film-coating material belt after the marks are cut, a forming mechanism for laminating the film-coating material belt after the chamfers, a dust removal conveying mechanism for conveying the pole pieces and removing dust, a CCD finished product detection mechanism for detecting the appearance of the film-coating material belt, and a material collecting mechanism for collecting traction;

the receiving mechanism comprises a servo motor and a receiving roller, and the servo motor is in transmission connection with the receiving roller.

Wherein, material area membrane material unwinding mechanism includes that the material area unreels the roller and the membrane material unreels the roller, and the material area is unreeled the roller and the membrane material is unreeled the roller and is all rotationally installed in the frame, and the material area is unreeled the roller or/and the membrane material is unreeled the top of roller and is equipped with material area locating piece and the ruddiness locator that is used for rectifying.

Wherein, straining device unreels tension control mechanism and unreels storage mechanism including being located material area membrane material unwinding mechanism top.

The unwinding tension control mechanism comprises a swing roller and a tension motor for controlling the swing of the swing roller, and the tension motor is connected with the swing roller through a connecting rod assembly; unreel storage mechanism and include storage motor, storage lead screw, storage nut, storage support and storage roller, the output shaft and the storage lead screw rigid coupling of storage motor, storage nut cover are established on the storage lead screw, storage support and storage nut rigid coupling, and the storage roller is rotationally installed on storage support.

The laser cutting mark mechanism comprises a fiber laser generator and a moving device driving the fiber laser generator to move in the horizontal direction.

Wherein, the below of laser cutting mark mechanism still is equipped with garbage collection mechanism, and garbage collection mechanism includes the waste bin and with the negative pressure passageway of waste bin intercommunication.

The CCD material belt detection mechanism and the CCD finished product detection mechanism are industrial cameras.

The chamfering and punching mechanism comprises a chamfering die and a die closing device for driving the chamfering die to close the die.

Wherein, forming mechanism includes that two symmetries set up the abdominal compression roller of both sides about the tectorial membrane material area and drive about two abdominal compression rollers in opposite directions or the drive arrangement of motion dorsad.

Wherein, dust removal conveying mechanism is including having the negative pressure conveyer belt of vacuum adsorption function, and the upside or/and the downside of negative pressure conveyer belt are equipped with dust collector.

The invention has the beneficial effects that: the working process of the laminating and die-cutting equipment is as follows: the method comprises the following steps that a material belt and a film material are placed on a material belt and film material unwinding mechanism, then the material belt is manually connected, the starting end of the material belt and the starting end of the film material are fixedly connected with a material receiving roller of a material receiving mechanism along the conveying direction, then a servo motor of the material receiving mechanism is started, so that the material belt and the film material are unwound by the material belt and film material unwinding mechanism, the material belt and the film material enter a station of a laser cutting mark mechanism through the guide of a tensioning mechanism, and the material belt and the film material are laminated and pre-laminated by the tensioning mechanism in the process that the material belt and the film material pass through the tensioning mechanism, so that a film-coated material belt is formed; when the film-coated material belt enters a station of the laser mark cutting mechanism, a servo motor of the material receiving mechanism is stopped firstly, then the laser mark cutting mechanism cuts the film-coated material belt to form a structure similar to a battery tab and the like on the film-coated material belt, after the laser mark cutting mechanism finishes cutting the film-coated material in the station, the servo motor of the material receiving mechanism is started again, the film-coated material belt after cutting mark continues to advance and enters a station of the CCD material belt detection mechanism, the CCD material belt detection mechanism detects the film-coated material belt after cutting mark, then the film-coated material belt after cutting mark enters a station of the chamfer mark cutting mechanism, after the chamfer cutting mechanism performs chamfer cutting on the material belt after cutting mark, and in the process of chamfer cutting, the chamfer cutting mechanism performs primary pressing on the material belt and the film material belt, namely secondary pre-laminating of the film-coated material belt, and the film-coated material belt after chamfer is pulled to the forming mechanism, carry out the shaping by forming mechanism to the tectorial membrane material area after the chamfer and compress tightly, secondary pressfitting material area and membrane material promptly to make material area and membrane material laminating shaping completely, then the tectorial membrane material area gets into dust removal conveying mechanism, carry the tectorial membrane material area and carry out dust removal work to the tectorial membrane material area at transportation process by dust removal conveying mechanism, then CCD finished product detection mechanism detects the outward appearance in tectorial membrane material area, accomplish the back that detects, the tectorial membrane material area is around rolling up in the receipts material roller outside, accomplish whole tectorial membrane cross cutting process.

Compared with the prior art, through laser shear mark mechanism, one set of receiving agencies of chamfer die-cutting mechanism and forming mechanism sharing, need not to set up a plurality of drive mechanism, equipment mechanism has been simplified, the cost of whole equipment has been reduced, receiving agencies adopts servo motor intermittent type formula action to carry out the shear mark, the stability of equipment has been improved, in addition, the mode that adopts the laser shear mark carries out the shear mark to the tectorial membrane material area, need not to use the production in tectorial membrane material area that many sets of mould just can be applicable to a plurality of models, the production cost is reduced, and the work efficiency is improved.

Drawings

The invention is further illustrated by means of the attached drawings, but the embodiments in the drawings do not constitute any limitation to the invention, and for a person skilled in the art, other drawings can be obtained on the basis of the following drawings without inventive effort.

Fig. 1 is a schematic structural diagram of the film laminating and die cutting apparatus in this embodiment.

Fig. 2 is a schematic structural diagram of another view angle of the film-coating and die-cutting apparatus in this embodiment.

Fig. 3 is an enlarged view of a portion a in fig. 2.

Fig. 4 is an enlarged view at B in fig. 2.

Fig. 5 is an enlarged view at C in fig. 1.

Fig. 6 is a schematic structural diagram of the laser scribing mechanism in the scribing state in this embodiment.

Fig. 7 is a schematic structural diagram of the laser scribing mechanism of the present embodiment after scribing.

Fig. 8 is an enlarged view at D in fig. 1.

Fig. 9 is an enlarged view at E in fig. 1.

Fig. 10 is an enlarged view at F in fig. 1.

Reference numerals: the device comprises a material belt film material unwinding mechanism 1, a material belt unwinding roller 111, a film material unwinding roller 112, a red light positioner 101, a material belt positioning block 102, a swing roller 21, a connecting rod assembly 22, a storage motor 23, a storage bracket 24, a storage roller 25, an unwinding tension control mechanism 3, an unwinding storage mechanism 4, a laser mark cutting mechanism 5, an optical fiber laser generator 51, a moving device 52, a waste collecting mechanism 6, a waste hopper 61, a negative pressure channel 62, a CCD material belt detection mechanism 7, a chamfering die cutting mechanism 8, a chamfering die 81, a die closing device 82, a material collecting roller 9, a forming mechanism 10, a belly pressure roller 121, a driving device 122, a dust removal conveying mechanism 11, a negative pressure conveying belt 1001, a dust removal device 1002, a CCD finished product detection mechanism 12, a rack 13 and a film coating material belt 14.

Detailed Description

The invention is further described with reference to the following examples.

The invention relates to a specific implementation mode of film-coating and die-cutting equipment, which is shown in fig. 1-2, and the film-coating and die-cutting equipment comprises a rack 13, wherein a material belt and film material unwinding mechanism 1 for unwinding a material belt and a film material, a tensioning mechanism for pre-bonding the material belt and the film material to form a film-coating material belt 14, a laser mark cutting mechanism 5 for cutting marks on the film-coating material belt 14, a CCD material belt detection mechanism 7 for detecting the appearance of the film-coating material belt 14 after the cutting marks, a chamfering and die-cutting mechanism 8 for cutting the film-coating material belt 14 after the cutting marks, a forming mechanism 10 for pressing the film-coating material belt 14 after the chamfering, a dust removal conveying mechanism 11 for conveying pole pieces and removing dust, a CCD finished product detection mechanism 12 for detecting the appearance of the film-coating material belt 14, and a material collecting mechanism for collecting and pulling are sequentially arranged in the rack 13 along the pole piece conveying direction.

In this embodiment, the receiving mechanism includes servo motor and receiving roller 9, and servo motor is connected with receiving roller 9 transmission, and specifically, receiving roller 9 passes through the pivot and the bearing is rotationally installed on frame 13, and receiving roller 9 and pivot rigid coupling, and the pivot can rotate for frame 13 through the bearing to servo motor's output shaft and pivot rigid coupling, thereby make servo motor can drive receiving roller 9 and rotate, thereby make receiving roller 9 as main draw gear.

In this embodiment, the material tape and film material unwinding mechanism 1 includes a material tape unwinding roller 111 and a film material unwinding roller 112, the material tape unwinding roller 111 and the film material unwinding roller 112 are respectively used for installing the material tape roll and the film material roll, and the material tape unwinding roller 111 and the film material unwinding roller 112 are both rotatably installed on the frame 13, and the rotatable manner of the material tape unwinding roller 111 and the film material unwinding roller 112 can refer to the above material receiving roller 9. Referring to fig. 3, a tape positioning block and a red light positioner 101 for deviation correction are disposed above the tape unwinding roller 111. It should be noted that the red light positioner 101 is a conventional deviation rectifying electronic component, and the tape positioning block can be driven by a motor or an air cylinder to extend and retract, so as to adjust the position of the tape and realize the function of deviation rectification. Of course, the above-mentioned material belt positioning block and the red light positioner 101 can also be arranged above the film unwinding roller 112, and the function of deviation correction can also be realized through the material belt positioning block and the red light positioner 101.

In this embodiment, the tensioning mechanism further includes an unwinding tension control mechanism 3 and an unwinding storage mechanism 4 located above the material tape film material unwinding mechanism 1. Specifically, referring to fig. 4 and 5, the unwinding tension control mechanism 3 includes a swing roller 21 and a tension motor for controlling the swing of the swing roller 21, and the tension motor is coupled to the swing roller 21 through a link assembly 22. And unreel storage mechanism 4 and include storage motor 23, storage lead screw, storage nut, storage support 24 and storage roller 25, the output shaft and the storage lead screw rigid coupling of storage motor 23, the storage nut cover is established on the storage lead screw, storage support 24 and storage nut rigid coupling, and storage roller 25 rotationally installs on storage support 24. Through setting up unreel tension control mechanism 3 and unreel storage mechanism 4, can adjust the elasticity in tectorial membrane material area 14 at any time, and, it can also carry out storage work to unreel storage mechanism 4, avoid stopping the problem that leads to whole equipment to shut down because of certain process of follow-up needs, through setting up unreel storage mechanism 4, even follow-up certain process is shut down, material area membrane material unwinding mechanism 1 still can keep normal feed, and unreel storage mechanism 4 and can collect the storage with unnecessary material area and membrane material this moment, the production continuation and the continuity of equipment have been improved.

In the present embodiment, referring to fig. 6 to 7, the laser scribing mechanism 5 includes a fiber laser generator 51 and a moving device 52 for driving the fiber laser generator 51 to move in a horizontal direction. Optical fiber laser generator 51 is pulse laser, and the laser that optical fiber laser generator 51 was launched, through shake mirror and field lens to the corresponding structure of tectorial membrane material area 14 cut mark shaping, can shake the motion trail of mirror and utilize mobile device 52 drive optical fiber laser generator 51 to remove corresponding position through changing to adjust the shaping structure, the suitability is strong, need not to design the product production use that multiple mould can satisfy many specifications. The specific working process is as follows: the servo motor of the material receiving mechanism adopts intermittent feeding, the conveying mode of the film-coated material belt 14 is one-step feeding and one-step stopping, after the servo motor of the material receiving mechanism stops feeding, the optical fiber laser generator 51 cuts the film-coated material belt 14 under the static environment that the film-coated material belt 14 stops, the moving device 52 drives the optical fiber laser generator 51 to move left and right, cut marks with certain length are realized, and after the cut marks are finished, the film-coated material belt 14 after the cut marks moves forward again and circulates in sequence.

In the present embodiment, referring to fig. 8, a scrap collecting mechanism 6 is further provided below the laser scoring mechanism 5, and the scrap collecting mechanism 6 includes a scrap hopper 61 and a negative pressure passage 62 communicating with the scrap hopper 61. The waste material that the cut mark got off makes through negative pressure passageway 62 and forms the negative pressure in the waste material fill 61 to collect the waste material, be convenient for recycle.

In this embodiment, the CCD material strip detecting mechanism 7 and the CCD finished product detecting mechanism 12 are both industrial cameras. It should be noted that the CCD strip detecting mechanism 7 and the CCD finished product detecting mechanism 12 are image recognition detecting devices conventionally used in the art, and the specific working principle and structure thereof can be easily known to those skilled in the art.

In this embodiment, referring to fig. 9, the chamfer punching mechanism 8 includes a chamfer die 81 and a mold clamping device 82 for driving the chamfer die 81 to clamp the mold, specifically, the chamfer die 81 may be a conventional die, the design of the die may be optionally set according to the requirement, and the mold clamping device 82 may use an air cylinder or an oil cylinder as a driving source to drive the die to clamp the mold. The forming mechanism 10 includes two belly pressure rollers 121 symmetrically disposed on the upper and lower sides of the film-coated material belt 14, and a driving device 122 for driving the two belly pressure rollers 121 to move toward or away from each other, it should be noted that the driving device 122 may employ a conventional air cylinder or oil cylinder as a driving source, and the belly pressure roller 121 may employ a roller body having a smooth plane.

In this embodiment, referring to fig. 10, the dust removing conveying mechanism 11 includes a negative pressure conveying belt 1001 with a vacuum adsorption function, and a dust removing device 1002 is disposed on each of upper and lower sides of the negative pressure conveying belt 1001. Dust collector 1002 has the brush, removes dust through the tectorial membrane material area 14 on the brush to negative pressure conveyer belt 1001, can avoid finished product tectorial membrane material area 14 to receive the dust pollution, guarantees the production quality in tectorial membrane material area 14.

The working process of the laminating and die-cutting equipment is as follows: firstly, a material belt and a film material are placed on a material belt and film material unwinding mechanism 1, then the material belt is manually connected, the starting end of the material belt and the starting end of the film material are fixedly connected with a material receiving roller 9 of a material receiving mechanism along the conveying direction, then a servo motor of the material receiving mechanism is started, so that the material belt and film material are unwound by the material belt and film material unwinding mechanism 1, the material belt and film material can enter a station of a laser mark cutting mechanism 5 through the guide of a tensioning mechanism, and the material belt and film material can be laminated and pre-laminated by the tensioning mechanism in the process that the material belt and film material pass through the tensioning mechanism, so that a film-coated material belt 14 is formed; after the film-coated material belt 14 enters the station of the laser mark cutting mechanism 5, the servo motor of the material receiving mechanism is stopped firstly, then the laser mark cutting mechanism 5 cuts the film-coated material belt 14 to form structures similar to battery tabs and the like on the film-coated material belt 14, after the laser mark cutting mechanism 5 finishes cutting the film-coated material in the station, the servo motor of the material receiving mechanism is started again, the film-coated material belt 14 after cutting mark continues to advance and enters the station of the CCD material belt detection mechanism 7, the film-coated material belt 14 after cutting mark is detected by the CCD material belt detection mechanism 7, then the film-coated material belt 14 after cutting mark enters the station of the chamfer mark cutting mechanism 8, the chamfer cutting mechanism 8 performs chamfer cutting on the film-coated material belt after cutting mark, and in the process of chamfer cutting, the chamfer cutting mechanism 8 performs primary pressing on the material belt and the film material belt, namely secondary pre-laminating of the film-coated material belt 14, and the chamfer-coated material belt 14 after chamfering is pulled to the forming mechanism 10, the membrane material area 14 after being chamfered is carried out the shaping by forming mechanism 10 and is compressed tightly, secondary pressfitting material area and membrane material promptly to make material area and membrane material laminate the shaping completely, then during membrane material area 14 entered into dust removal conveying mechanism 11, carry membrane material area 14 and carry out dust removal work to membrane material area 14 at transportation process by dust removal conveying mechanism 11, then CCD finished product detection mechanism 12 detects the outward appearance in membrane material area 14, accomplish the back that detects, membrane material area 14 is around rolling up in the receipts material roller 9 outside, accomplish whole membrane die cutting process.

Compared with the prior art, through laser shear mark mechanism 5, one set of receiving agencies of chamfer die-cutting mechanism 8 and forming mechanism 10 sharing, need not to set up a plurality of drive mechanism, equipment mechanism has been simplified, the cost of whole equipment has been reduced, receiving agencies adopts servo motor intermittent type formula action to carry out the shear mark, the stability of equipment has been improved, in addition, the mode that adopts the laser shear mark carries out the shear mark to tectorial membrane material area 14, need not to use many sets of moulds just can be applicable to the production in tectorial membrane material area 14 of a plurality of models, the production cost is reduced, and the work efficiency is improved.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention, and not for limiting the protection scope of the present invention, although the present invention is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention.

Claims (10)

1. The utility model provides a tectorial membrane cross cutting equipment which characterized in that: the device comprises a rack, wherein a material belt and film material unwinding mechanism for unwinding a material belt and a film material, a tensioning mechanism for pre-bonding the material belt and the film material to form a film-coated material belt, a laser mark cutting mechanism for cutting a mark on the film-coated material belt, a CCD material belt detection mechanism for detecting the appearance of the film-coated material belt after the mark is cut, a chamfering die cutting mechanism for cutting the film-coated material belt after the mark is cut, a forming mechanism for pressing the film-coated material belt after the chamfer is cut, a dust removal conveying mechanism for conveying the pole pieces and removing dust, a CCD finished product detection mechanism for detecting the appearance of the film-coated material belt, and a material collecting mechanism for collecting and drawing are sequentially arranged in the rack along the pole piece conveying direction;

the receiving mechanism comprises a servo motor and a receiving roller, and the servo motor is in transmission connection with the receiving roller.

2. The film-laminating die-cutting apparatus of claim 1, wherein: the material belt film material unwinding mechanism comprises a material belt unwinding roller and a film material unwinding roller, the material belt unwinding roller and the film material unwinding roller are both rotatably installed on the rack, and a material belt positioning block and a red light positioner used for deviation correction are arranged above the material belt unwinding roller or/and the film material unwinding roller.

3. The film-laminating die-cutting apparatus of claim 1, wherein: the tensioning mechanism comprises an unreeling tension control mechanism and an unreeling material storage mechanism which are located above the material belt film material unreeling mechanism.

4. The film-laminating die-cutting apparatus of claim 3, wherein: the unreeling tension control mechanism comprises a swing roller and a tension motor for controlling the swing of the swing roller, and the tension motor is connected with the swing roller through a connecting rod assembly; unreel storage mechanism includes storage motor, storage lead screw, storage nut, storage support and storage roller, the output shaft of storage motor with storage lead screw rigid coupling, storage nut cover is established on the storage lead screw, the storage support with storage nut rigid coupling, the storage roller is rotationally installed on the storage support.

5. The film-laminating die-cutting apparatus of claim 1, wherein: the laser mark cutting mechanism comprises a fiber laser generator and a moving device driving the fiber laser generator to move in the horizontal direction.

6. The film-laminating die-cutting apparatus of claim 1, wherein: the laser cutting mark mechanism is characterized in that a waste collecting mechanism is further arranged below the laser cutting mark mechanism, and the waste collecting mechanism comprises a waste hopper and a negative pressure channel communicated with the waste hopper.

7. The film-laminating die-cutting apparatus of claim 1, wherein: the CCD material belt detection mechanism and the CCD finished product detection mechanism are both industrial cameras.

8. The film-laminating die-cutting apparatus of claim 1, wherein: the chamfer punching mechanism comprises a chamfer mould and a mould closing device for driving the chamfer mould to close the mould.

9. The film-laminating die-cutting apparatus of claim 1, wherein: the forming mechanism comprises two abdomen pressing rollers which are symmetrically arranged on the upper side and the lower side of the film-coated material belt and a driving device which drives the abdomen pressing rollers to move oppositely or backwards.

10. The film-laminating die-cutting apparatus of claim 1, wherein: the dust removal conveying mechanism comprises a negative pressure conveying belt with a vacuum adsorption function, and a dust removal device is arranged on the upper side or/and the lower side of the negative pressure conveying belt.

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