CN115535698A

CN115535698A - Integrated cutting and stacking device for composite POE conductive adhesive film and operation method

Info

Publication number: CN115535698A
Application number: CN202211523439.3A
Authority: CN
Inventors: 苏丹; 刘苗苗; 刘妮坤; 罗锦珩; 戚绿秧
Original assignee: Zhejiang Xiangbang Technology Co ltd
Current assignee: Zhejiang Xiangbang Technology Co ltd
Priority date: 2022-12-01
Filing date: 2022-12-01
Publication date: 2022-12-30
Anticipated expiration: 2042-12-01
Also published as: CN115535698B

Abstract

The invention discloses an integrated cutting piece stacking device of a composite POE conductive adhesive film, which comprises a machine body, wherein a feed inlet of the machine body can be provided with an adhesive film roller which can be arranged into a roller, a cutting piece part is arranged in the machine body, and the cutting piece part comprises: the cutting assembly is rotatably arranged on the inner side of the machine body, a friction structure is arranged on the inner side of the cutting assembly, and the friction structure is fixed in the machine body and can be in contact with the cutting assembly; the guide assembly is rotatably arranged in the machine body, one side of the guide assembly is provided with a discharge frame, and the inner side of the discharge frame is provided with a plurality of groups of air outlets which penetrate through the discharge frame; the flexible subassembly is fixed in inside the organism, flexible subassembly sets up directly over the direction subassembly, and the structure is decided to the inboard setting in bottom of flexible subassembly, decide the structure can with direction subassembly looks adaptation. The cutting device can cut the adhesive film, and the adhesive film can be automatically stacked after the cutting, so that the adhesive film can be stably cut.

Description

Integrated cutting and stacking device for composite POE conductive adhesive film and operation method

Technical Field

The invention relates to the technical field of conductive adhesive film processing, in particular to an integrated cutting piece stacking device for a composite POE conductive adhesive film and an operation method.

Background

POE has the dual advantages of plastics and rubber, and can be widely applied to the fields of automobile parts, packaging adhesive films of photovoltaic modules, medical packaging materials, building materials and the like. In the process of processing the conductive adhesive film, the conductive adhesive film is mostly processed into a coiled adhesive film, and then the adhesive film is cut according to the occasion and length required.

But the condition that the inside glue solution of glued membrane attaches on the piece surface can appear cutting the piece in-process to the glued membrane, can appear the condition that the sharpness reduces after using a period of time, and can not be stable pile up the glued membrane after carrying out the piece, need artifically assist it.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an integrated cutting piece stacking device of a composite POE conductive adhesive film and an operation method, and solves the problems that the situation that the adhesive liquid in the adhesive film is attached to the surface of a cutting piece in the process of cutting the adhesive film at present, the sharpness is reduced after the adhesive film is used for a period of time, the adhesive film cannot be stably stacked after the cutting is carried out, and the adhesive film needs to be manually assisted.

In order to achieve the purpose, the invention is realized by the following technical scheme: whole device of piling up of integration cut-parts of compound POE conductive adhesive film, which comprises a bod, the glued membrane roller of roller can be installed to the feed inlet position of organism, and the inside of organism sets up cut-parts, cut-parts portion includes:

the cutting assembly is rotatably arranged on the inner side of the machine body, a friction structure is arranged on the inner side of the cutting assembly, and the friction structure is fixed in the machine body and can be in contact with the cutting assembly;

the guide assembly is rotatably arranged in the machine body, one side of the guide assembly is provided with a discharge frame, and the inner side of the discharge frame is provided with a plurality of groups of air outlets which penetrate through the discharge frame;

the telescopic assembly is fixed inside the machine body and is arranged right above the guide assembly, and the bottom inner side of the telescopic assembly is provided with a cutting structure which can be matched with the guide assembly.

Furthermore, one side of the discharging frame close to the guide assembly is inclined, and the air outlet hole is located at the inclined tail end of the discharging frame.

Further, the cutting assembly includes:

the output end of the cutting motor penetrates through the machine body and is movably connected with the machine body, and a plurality of parallel cutting sheets are fixedly sleeved on the outer side of the output end of the cutting motor;

the auxiliary groove is arranged on the inner side of the machine body.

Further, the friction structure includes:

the fixing frame is fixed on the inner side of the machine body and extends downwards to the position between the cutting sheets, and a friction block which can extend to the outer side of the fixing frame is arranged on the inner side of the fixing frame;

the electromagnet is movably arranged in the fixing frame, the upper end and the lower end of the electromagnet are provided with clamping blocks capable of limiting the electromagnet, and the clamping blocks are fixed on the outer surface of the electromagnet;

the telescopic frame is slidably mounted on the inner side of the fixing frame, the roller is arranged on the inner side of the telescopic frame, and the compression spring is arranged on the inner side of the telescopic frame and used for supporting the telescopic frame;

and the sliding rheostat is fixed on the outer surface of the fixing frame, and the sliding position of the sliding rheostat is connected with the telescopic frame.

Furthermore, one side of the friction block close to the electromagnet is provided with a magnetic plate, and the electromagnet can control the position of the friction block after being electrified.

Further, the guide assembly includes:

the driving disc is movably arranged on the inner side of the machine body, and a fixed rod fixedly connected with the machine body is arranged on the inner side of the driving disc;

the roof, the activity sets up in the driving-disc inboard, the outside of roof sets up can carry out the complex supporting shoe with deciding the structure, and the supporting shoe is fixed in the roof outside, the outside of roof sets up the spout.

Further, the telescopic assembly comprises:

the hydraulic cavity is fixed on the inner side of the machine body, a push plate is arranged inside the hydraulic cavity, and a telescopic rod is arranged on one side of the push plate;

the locating grooves are arranged on the inner side of the hydraulic chamber and are symmetrically arranged.

Further, decide the structure and include:

the movable block is telescopically arranged in the hydraulic chamber, a clamping block is arranged on the outer side of the movable block, clamping plates are arranged at the ends, extending to the hydraulic chamber, of the movable block and the clamping block, and the clamping plates are used for assisting the movement of the movable block and the clamping block;

and the cutting piece is fixed at the bottom of the moving block.

The invention also provides an operation method of the integrated cutting piece stacking device for the composite POE conductive adhesive film, which comprises the following steps:

arranging an adhesive film to be cut into pieces between the machine bodies, inserting the adhesive film into the adhesive film roller by using a rod-shaped object to form a support for the adhesive film roller, and then drawing the adhesive film to enable the adhesive film to penetrate through the cutting assembly;

the cutting assembly cuts the adhesive film, a part of adhesive liquid on the inner side of the adhesive film is attached to the outer side of the cutting assembly, and the friction structure rubs the cutting assembly by increasing the thickness.

The glued membrane enters into the direction subassembly inboard, decides the glued membrane under the action of flexible subassembly and cutting structure.

Furthermore, after the hydraulic oil is extruded, the cutting structure can move twice, and the adhesive film is firstly clamped and then cut.

Advantageous effects

The invention provides an integrated cutting and stacking device for a composite POE conductive adhesive film and an operation method. Compared with the prior art, the method has the following beneficial effects:

1. the cutting machine can cut the adhesive film, and the adhesive film can be automatically stacked after the cutting, so that the adhesive film can be stably cut, the processing can be quickly and efficiently carried out, the trouble of manually cutting the adhesive film is avoided, the stability of the adhesive film can be ensured in the cutting process, and the cutting stability is ensured.

2. According to the invention, the cutting assembly capable of cutting the adhesive film is arranged, so that the adhesive film can be cut into a plurality of mutually independent adhesive films, and once excessive adhesive liquid attached to the outer surface of the cut piece is generated in the using process, the adhesive film can be automatically rubbed and cleaned, thereby ensuring the stable cutting effect of the cut piece.

3. According to the cutting device, the cutting structure capable of cutting the adhesive films is arranged, so that a plurality of adhesive films can be cut into the adhesive film pieces in the using process, automatic cutting can be performed according to the movement distance of the adhesive films, and the adhesive films on two sides of the cutting position can be clamped and fixed in the cutting process, so that the cutting stability can be ensured.

4. According to the invention, the recovery frame capable of conveniently stacking the adhesive films is arranged, after the adhesive films enter the recovery frame, the air can be exhausted from the positions with higher inclination angles of the adhesive films, so that one side of the adhesive films can quickly fall down, and therefore, the stable fixation after the adhesive films fall down can be ensured, and the occurrence of unstable stacking caused by the upright adhesive films is avoided.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a cross-sectional view of the housing of the present invention;

FIG. 3 is a first partial schematic view of the present invention;

FIG. 4 is a side view of the cutting assembly of the present invention;

FIG. 5 is a schematic view of the friction structure of the present invention;

FIG. 6 is a cross-sectional view of a friction structure of the present invention;

FIG. 7 is an exploded view of the friction structure of the present invention;

FIG. 8 is a second partial schematic view of the present invention;

FIG. 9 is an exploded view of a portion of the structure of the present invention;

FIG. 10 is a schematic view of the telescoping assembly and cutting structure of the present invention;

FIG. 11 is an exploded view of the telescoping assembly and cutting structure of the present invention;

FIG. 12 is a bottom view of the hydraulic chamber configuration of the present invention;

FIG. 13 is a schematic view of a guide structure of the present invention;

FIG. 14 is an exploded view of the guide structure of the present invention;

fig. 15 is a schematic diagram of a sliding resistor control electromagnet according to the present invention.

In the figure: the cutting machine comprises a machine body 1, a glue film roller 2, a cutting assembly 21, a friction structure 22, a guide assembly 23, a cutting structure 24, a telescopic assembly 25, a discharging frame 26, a cutting motor 211, a cutting piece 212, an auxiliary groove 213, a fixing frame 221, a friction block 222, an electromagnet 223, a clamping block 224, an expansion bracket 225, a compression spring 226, a slide rheostat 227, a roller 228, a clamping groove 229, a driving disc 231, a fixing rod 232, a top plate 233, a supporting block 234, a sliding groove 235, a moving block 241, a clamping block 242, a cutting piece 243, a clamping plate 244, a hydraulic chamber 251, a push plate 252, a telescopic rod 253 and a positioning groove 255.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Referring to fig. 1-15, the present invention provides an integrated cutting and stacking apparatus for a composite POE conductive adhesive film, which is used to cut a roll of adhesive film into adhesive film pieces with the same size, and includes a machine body 1, an adhesive film roll 2 capable of being mounted at a feed port of the machine body 1, and the adhesive film roll 2 is capable of rotating inside the machine body 1, and is characterized in that a cutting piece portion is disposed inside the machine body 1, and the adhesive film roll 2 is output as a stacked adhesive film piece after being processed by the cutting piece portion, and the cutting piece portion includes:

the cutting assembly 21 is rotatably arranged on the inner side of the machine body 1, the adhesive film output by the adhesive film roller 2 can be cut into a plurality of adhesive films after passing through the cutting assembly 21, wherein the inner side of the cutting assembly 21 is provided with a friction structure 22, the friction structure 22 is fixed in the machine body 1, and the adhesive film can be in contact with the cutting assembly 21 when the adhesive solution attached to the cutting assembly 21 is excessive;

the guide assembly 23 is rotatably arranged in the machine body 1, one side of the guide assembly 23 is provided with a discharge frame 26, the bottom of the discharge frame 26 is flush with the bottom of the machine body 1 and can be placed and fixed on the ground, and a plurality of groups of air outlet holes are formed in the inner side of the discharge frame 26 and penetrate through the discharge frame 26;

the flexible subassembly 25 is fixed in inside 1 organism, and flexible subassembly 25 sets up directly over guide assembly 23, and the structure 24 is decided to the inboard setting in bottom of flexible subassembly 25, decides structure 24 and can with guide assembly 23 looks adaptation, form the spacing centre gripping to the glued membrane.

In the present invention, the adhesive film roller 2 outputs the adhesive film along the inner surface of the machine body 1, and the adhesive film is converted into a plurality of independent adhesive films by the cutting assembly 21, and then the independent adhesive films are cut by the cutting mechanism 24 through the cutting of the cutting mechanism 24, so that the independent square adhesive films can be formed.

In an embodiment, one side of the discharging frame 26 close to the guiding component 23 is inclined, and the inclination angle is 45 °, and the air outlet is located at the end position of the inclined discharging frame 26, after the adhesive film falls into the inside of the discharging frame 26, parallel to the adhesive film, and both presenting inclined shape, and the air outlet is the higher side of the adhesive film.

In this embodiment, can carry out carminative venthole through the setting, make the glued membrane enter into the inside back of blown down frame 26, with the quick discharge of the gas of higher one side to make the quick parallel state of transition of glued membrane, the skew of position can not appear after falling into blown down frame 26 inside.

In one embodiment, cutting assembly 21 comprises:

the cutting motor 211, one end of which extending out of the output shaft is fixed on the outer surface of the machine body 1, the output end of the cutting motor 211 penetrates through the machine body 1 and is movably connected with the machine body 1, the cutting motor 211 can rotate relative to the machine body 1 after being electrified, and a plurality of parallel cutting pieces 212 are fixedly sleeved on the outer side of the output end of the cutting motor 211;

the auxiliary groove 213 is formed inside the machine body 1 and is used for accommodating the cutting piece 212, so that the cutting piece 212 is prevented from touching the machine body 1 in the movement process to cause damage to the machine body 1.

In this embodiment, the plurality of parallel cutting sheets 212 are used to cut the adhesive film to output a plurality of unconnected independent adhesive films, and the cutting sheets 212 have a certain thickness, so that the adhesive film between the cutting sheets 212 is bent after the adhesive film is cut, thereby ensuring the stability of the output of the adhesive film, so that the adhesive film does not bend downwards at the first time when the adhesive film is separated from the machine body 1, and can stably enter the inner side of the guide assembly 23.

In one embodiment, the friction structure 22 includes:

the fixing frame 221 is fixed on the inner side of the machine body 1 and extends downwards to the position between the cutting sheets 212, the inner side of the fixing frame 221 is provided with friction blocks 222 capable of extending to the outer side of the fixing frame 221, wherein the friction blocks 222 are symmetrically arranged, and one end of each friction block 222 extending to the outer side of the fixing frame 221 can be contacted with the cutting sheets 212;

the electromagnet 223 is movably arranged in the fixing frame 221, the upper end and the lower end of the electromagnet are provided with a fixture block 224 capable of limiting the electromagnet 223, the fixture block 224 is fixed on the outer surface of the electromagnet 223, the outer side of the fixture block 224 is provided with a clamping groove 229 capable of limiting the fixture block 224, and the clamping groove 229 can limit the moving distance of the fixture block 224, so that the fixture block 224 can only move for a certain distance;

an expansion bracket 225 slidably mounted inside the fixed bracket 221, wherein a roller 228 is provided inside the expansion bracket 225, and the roller 228 is in contact with the cutting blade 212, so that when the adhesive solution adhering to the cutting blade 212 is excessive, the roller 228 can contract inward to change the position of the expansion bracket 225, and a compression spring 226 is provided inside the expansion bracket 225, and the compression spring 226 is used for supporting the expansion bracket 225;

the slide rheostat 227 is fixed to the outer surface of the fixed frame 221, and the slide rheostat 227 is connected to the telescopic frame 225 at a slide adjusting position, so that the resistance value of the slide rheostat 227 can be changed when the telescopic frame 225 is shifted.

In this embodiment, the position of the telescopic frame 225 can be changed by attaching the glue solution to the cut piece 212 after the cutting to increase the thickness, and the resistance value of the slide rheostat 227 can be changed after the position of the telescopic frame 225 is changed, so that the current of the electromagnet 223 is controlled to be changed, the magnetic force of the electromagnet 223 is changed, and the friction block 222 is pushed out.

In one embodiment, the friction block 222 is arranged as a magnetic plate on the side close to the electromagnet 223, and can be influenced by the electromagnet 223 during use, the electromagnet 223 can control the position of the friction block 222 after being electrified, and the position distance between the electromagnet 223 and the friction block 222 on the two sides is the same.

In this embodiment, the electromagnet can push the friction blocks 222 on both sides outward after being energized, so that the friction blocks 222 are in contact with the cut pieces 212 on both sides, and the adhesive solution adhering to the outer sides of the cut pieces 212 is removed by the friction between the friction blocks 222 and the cut pieces 212, so that the cut pieces 212 are sharpened.

In one embodiment, the guide assembly 23 includes:

the driving disc 231 is movably mounted on the inner side of the machine body 1, the inner side of the driving disc 231 is provided with a fixing rod 232 fixedly connected with the machine body 1, the cross section of the part, located on the inner side of the driving disc 231, of the fixing rod 232 is oval, and the driving disc 231 can rotate on the outer side of the fixing rod 232;

the top plate 233 is movably arranged on the inner side of the driving disc 231, a complete circular ring can be formed by combining the top plates 233, the outer side of the top plate 233 is provided with a supporting block 234 capable of being matched with the cutting structure 24, the supporting block 234 is fixed on the outer side of the top plate 233, a recess is formed in the inner side of the supporting block 234, the outer side of the top plate 233 is provided with a sliding groove 235, the sliding groove 235 is arranged on the outer surface of the driving disc 231 on the outer side of the top plate 233, and the sliding groove 235 can limit the top plate 233.

In this embodiment, the portion of the driving disc 231 extending to the outside of the machine body 1 is a gear, a meshing gear capable of being used for driving is arranged on the outside of the gear, the meshing gear is driven by a guiding motor, the guiding motor drives the meshing gear to rotate, and therefore the driving gear rotates, and the driving disc 231 on the other side is driven to synchronously move by the top plate 233 while the driving disc 231 rotates.

In one embodiment, retraction assembly 25 comprises:

a hydraulic chamber 251 fixed inside the machine body 1, a push plate 252 dividing the hydraulic chamber 251 into two chambers which are not communicated with each other is arranged inside the hydraulic chamber 251, an expansion link 253 is arranged on one side of the push plate 252, the installation end of the expansion link 253 is fixed on the inner wall of the hydraulic chamber 251, and the contraction end of the expansion link 253 is fixedly connected with the push plate 252;

the positioning grooves 255 are formed inside the hydraulic chamber 251, and the positioning grooves 255 are symmetrically arranged.

In this embodiment, the inside of the hydraulic chamber 251 is filled with hydraulic oil, wherein the hydraulic oil is only filled at the bottom of the push plate 252, and the push plate 252 moves to extrude the hydraulic oil, so that the pressure inside the hydraulic oil is increased, thereby forming the linkage of the cutting structure 24.

In one embodiment, severing structure 24 comprises:

the moving block 241 is telescopically arranged in the hydraulic chamber 251, a clamping block 242 is arranged on the outer side of the moving block 241, the connection mode between the clamping block 242 and the hydraulic chamber 251 is the same as that between the moving block 241 and the hydraulic chamber 251, clamping plates 244 are arranged at one ends of the moving block 241 and the clamping block 242 extending to the hydraulic chamber 251, and the clamping plates 244 are used for assisting the moving block 241 and the clamping block 242 to move;

and a cut-off piece 243 fixed to the bottom of the moving block 241 and capable of extending into the concave portion of the supporting block 234.

In this embodiment, when the push plate 252 pushes the hydraulic chamber 251 to pressurize hydraulic oil, the hydraulic oil can push the clamping plate 244, the moving block 241 and the clamping block 242 are pushed out by the clamping plate 244, so as to realize the movement therebetween, protrusions which can extend into the positioning grooves 255 are formed at both ends of the moving block 241 and the clamping block 242, and the moving positions of the moving block 241 and the clamping block 242 are limited by the positioning grooves 255.

The embodiment of the invention also provides an operation method of the integrated cutting and stacking device for the composite POE conductive adhesive film, which comprises the following steps:

the adhesive film to be cut is arranged between the machine bodies 1, then a rod-shaped object is inserted into the adhesive film roller 2 to form a support for the adhesive film roller 2, and then the adhesive film is pulled to pass through the cutting assembly 21.

During operation, start cutting motor 211 and guide motor, set up the gyro wheel 228 that can carry out the rolling to the glued membrane simultaneously in the ejection of compact position of organism 1, the gyro wheel 228 of rolling keeps the same velocity of motion with cutting motor 211.

The cutting piece 212 cuts the adhesive film under the driving of the cutting motor 211, a part of the adhesive liquid on the inner side of the adhesive film is attached to the outer surface of the cutting piece 212, the thickness of the cutting piece 212 is increased after the adhesive liquid is attached, so that the roller 228 is pushed, the roller 228 contracts to compress the telescopic frame 225 inwards, the resistance value of the sliding rheostat 227 is changed after the telescopic frame 225 contracts, the power supply current of the electromagnet is changed, and the magnetic force is changed accordingly.

The glued membrane after cutting piece 212 enters into driving-disc 231 inboard, is supported by supporting shoe 234 simultaneously, and telescopic link 253 is flexible to be changed, makes push pedal 252 promote hydraulic oil, and under the effect of cardboard 244, grip block 242 moves down at first, forms the centre gripping to the glued membrane with supporting shoe 234, and later the movable block 241 promotes cutting piece 243 and decides the glued membrane.

In one embodiment, after the hydraulic oil is squeezed, the clamping block 242 moves first, and the clamping block 242 and the supporting block 234 form a clamping to the adhesive film, and the weight of the moving block 241 is 80% of that of the clamping block 242, and since the clamping block 242 is heavier and moves downward, the clamping block 242 moves downward first.

Wherein, decide to form the speed difference between motor and the direction motor, the speed of direction motor pivoted is higher than deciding 20% of motor rotational speed, and the direction motor is discontinuous work, and shut down when utilizing the cutting piece 243 to decide.

The invention relates to the prior art of both circuits and electronic components, and can be completely realized by those skilled in the art without needless explanation, and the protection content of the invention also does not relate to the improvement of an internal structure and a method.

And those not described in detail in this specification are well within the skill of those in the art.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. Integral cut-parts stacking device of compound POE conductive adhesive membrane, which comprises a bod, the glued membrane roller of roller can be installed to the feed inlet position of organism, its characterized in that, the inside of organism sets up cut-parts, cut-parts portion includes:

2. The integrated cutting and stacking device for the composite POE conductive adhesive film according to claim 1, wherein the integrated cutting and stacking device comprises: one side of the discharging frame close to the guide assembly is inclined, and the air outlet hole is located at the tail end of the inclined discharging frame.

3. The integrated cutting piece stacking device for the composite POE conductive adhesive film according to claim 1, which is characterized in that: the cutting assembly includes:

the auxiliary groove is arranged on the inner side of the machine body.

4. The integrated cutting piece stacking device for the composite POE conductive adhesive film according to claim 3, wherein: the friction structure includes:

the electromagnet is movably arranged in the fixing frame, clamping blocks capable of limiting the electromagnet are arranged at the upper end and the lower end of the electromagnet, and the clamping blocks are fixed on the outer surface of the electromagnet;

5. The integrated cutting piece stacking device for the composite POE conductive adhesive film according to claim 4, wherein: the side of the friction block close to the electromagnet is provided with a magnetic plate, and the electromagnet can control the position of the friction block after being electrified.

6. The integrated cutting piece stacking device for the composite POE conductive adhesive film according to claim 4, wherein: the guide assembly includes:

7. The integrated cutting piece stacking device for the composite POE conductive adhesive film according to claim 6, wherein: the telescoping assembly comprises:

8. The integrated cutting piece stacking device for the composite POE conductive adhesive film according to claim 7, wherein: decide the structure and include:

the clamping device comprises a moving block, a clamping block and a clamping block, wherein the moving block is telescopically arranged in a hydraulic cavity, a clamping block is arranged on the outer side of the moving block, clamping plates are arranged at the ends, extending to the hydraulic cavity, of the moving block and the clamping block, and the clamping plates are used for assisting the moving of the moving block and the clamping block;

and the cutting piece is fixed at the bottom of the moving block.

9. An operation method of the integrated cutting and stacking device for the composite POE conductive adhesive film as claimed in any one of claims 1 to 8, wherein: the method comprises the following steps:

arranging an adhesive film to be cut into pieces between the machine bodies, inserting the adhesive film into the adhesive film roller by using a rod-shaped object to form a support for the adhesive film roller, and then drawing the adhesive film to enable the adhesive film to pass through the cutting assembly;

the cutting assembly cuts the adhesive film, a part of adhesive liquid on the inner side of the adhesive film is attached to the outer side of the cutting assembly, and the friction structure rubs the cutting assembly by increasing the thickness;

10. The operation method of the integrated cutting-piece stacking device for the composite POE conductive adhesive film according to claim 9, wherein the operation method comprises the following steps: after the hydraulic oil is extruded, the cutting structure can generate two movements, and the adhesive film is firstly clamped and then cut.