CN214377791U - Advancing type hot-pressing wire embedding device - Google Patents

Abstract

The utility model provides a marching type hot-pressing buries a device belongs to conductive film or heat conduction membrane production facility technical field, include: a motion mechanism; the mounting plate is connected with the motion mechanism, and the motion mechanism can drive the mounting plate to move; the bottom plate is positioned below the mounting plate and used for placing a membrane body; the wire feeding mechanism is connected with the mounting plate and is used for conveying metal wires to the film body on the bottom plate; and the hot pressing mechanism is connected with the mounting plate and is used for hot pressing the metal wires into the membrane body. The utility model has the advantages that: this hot pressing buries a device can bury the wire to the internal of diaphragm automatically, carries out the hot pressing to the transparent diaphragm body of cloth silk simultaneously, makes the wire can get into the internal portion of diaphragm completely, so the wire is difficult for separating with the diaphragm body.

Description

Advancing type hot-pressing wire embedding device

Technical Field

The utility model belongs to the technical field of conducting film or heat-conducting film production facility, a marching type hot pressing buries a device is related to.

Background

With the development of electronic technology, conductive wires such as metal wires are disposed on a transparent film substrate in various ways to form a transparent conductive film or a heat conductive film, and such products are currently used in various fields, such as automobiles, solar cells, light emitting elements, display devices, touch panels, and the like. The current mode of thread burying has a lot, has to glue, glues and paste etc. also often in addition impresses the wire in the recess that sets up in advance on the transparent film through the pressurization mode, but this kind of method appears the phenomenon that drops easily through long-time, consequently needs a new technique to provide this kind of membrane product of steady quality.

Currently, a utility model patent application No. 200910179972.0 discloses a method for manufacturing a conductive film and a conductive film manufactured by the method. The method comprises the following steps: pretreating the carbon nanotubes by at least one of a cutting step using ultrasonic waves and a chemical reaction step using an acid; dispersing the carbon nanotubes in a solvent; mixing a metal wire with the dispersion solution of the carbon nanotubes; and forming an electrode layer by coating the mixed resultant on a substrate.

In the above method for manufacturing a conductive film, the metal wire can be attached to the surface of the transparent film, but the metal wire cannot completely enter the film, and the metal wire may be separated from the film, so that the quality of the product is unstable, and the yield of the product is affected.

Disclosure of Invention

The utility model aims at the above-mentioned problem that prior art exists, provide a marching type hot pressing buries a device.

The purpose of the utility model can be realized by the following technical proposal: a traveling hot-pressing wire embedding device comprising:

the movement mechanism is provided with six mechanical arms;

the mounting plate is connected with the motion mechanism, and the motion mechanism can drive the mounting plate to move;

the bottom plate is positioned below the mounting plate and used for placing a membrane body;

the wire feeding mechanism is connected with the mounting plate and is used for conveying metal wires to the film body on the bottom plate;

and the hot pressing mechanism is connected with the mounting plate and is used for hot pressing the metal wires into the membrane body.

Preferably, the cutting device is connected with the mounting plate and is used for cutting the metal wire conveyed by the wire feeding mechanism.

Preferably, wire feeding mechanism includes motor, take-up reel, guide roller and stand pipe, the motor guide roller and the stand pipe all with mounting panel fixed connection, the take-up reel with the motor is connected, and the wire is around rolling up on the take-up reel and passing in proper order guide roller and the stand pipe.

Preferably, the wire feeding mechanism further comprises a guide ring, the guide ring is fixedly connected with the mounting plate, and the guide ring is located between the guide roller and the wire winding roll.

Preferably, the hot-pressing mechanism comprises a fixed seat, a heat-conducting column, a heating body and a ball end, the fixed seat is connected with the mounting plate, the heat-conducting column is connected with the fixed seat, the heating body is inserted into the heat-conducting column, and the ball end is connected with the heat-conducting column and faces towards the bottom plate.

Preferably, the hot pressing mechanism further comprises a floating seat and an elastic part, the fixed seat is provided with a shaft sleeve, the heat conducting column is movably arranged in the shaft sleeve in a penetrating mode, the floating seat is connected with the heat conducting column, and two ends of the elastic part are respectively connected with the floating seat and the fixed seat.

Preferably, the hot pressing mechanism comprises a fixed seat, a roller seat, a heating body and a roller end, the fixed seat is connected with the mounting plate, the roller seat is connected with the fixed seat, the roller end is connected with the roller seat and faces the bottom plate, and the heating body is inserted into the roller end.

Preferably, the hot pressing mechanism further comprises an elastic member, the roller seat is provided with a movable shaft, the fixing seat is provided with a shaft sleeve, the movable shaft is movably arranged in the shaft sleeve in a penetrating mode, and two ends of the elastic member are respectively connected with the roller seat and the fixing seat.

Preferably, the shutdown mechanism includes displacement cylinder, clamping jaw cylinder and blade, displacement cylinder with the mounting panel is connected, clamping jaw cylinder with displacement cylinder's piston rod is connected, the blade with clamping jaw cylinder is connected and is used for cutting off the wire.

Preferably, the bottom plate comprises a vacuum platform and a positioning pin, the vacuum platform is used for sucking the membrane body, the positioning pin is arranged on the vacuum platform in a penetrating mode, and the positioning pin is used for penetrating through the membrane body.

Compared with the prior art, the beneficial effects of the utility model are that:

1. this hot pressing buries a device can bury the wire to the internal of diaphragm automatically, carries out the hot pressing to the transparent diaphragm body of cloth silk simultaneously, makes the wire can get into the internal portion of diaphragm completely, so the wire is difficult for separating with the diaphragm body.

2. The cutting mechanism can cut off the metal wire after the wire embedding is finished, and the metal wire can be always kept right below the hot pressing mechanism by drawing the metal wire after the cutting mechanism is cut off before the next product is processed.

3. When the motor rotates, the winding roll can be driven to rotate, so that the metal wire is released, passes through the guide roller, penetrates through the guide pipe and then is guided to the film body; in addition, the movement mechanism can drive the hot pressing mechanism on the mounting plate to move along a set track, so that the metal wires can be arranged into a designed pattern.

4. In order to reduce the influence of the planeness of the moving mechanism and the bottom plate, the ball end needs to slightly float up and down; and because the whole dead weight of the ball end is larger, the contact area of the ball end and the transparent film body is small, and the single-point pressure and temperature are possibly too high, the film body is deformed, so that a floating seat and an elastic part are needed to be added, the floating seat is pushed upwards through a spring to offset the whole dead weight, and the pressure of the ball end on the film body is reduced.

5. The contact area of the roller end and the film body is large, and insufficient pressure possibly exists, so that the roller end always moves on the surface of the film body, and the metal wire cannot be pressed into the film body, so that an elastic piece needs to be added, the roller seat and the roller end are pushed downwards through the elastic piece, the pressure of the roller end on the film body is increased, and the metal wire can be pressed into the film body.

Drawings

Fig. 1 is a schematic structural view of the traveling hot-pressing wire burying device of the present invention.

Fig. 2 is the structural schematic diagram of the hot-pressing wire burying device of the present invention when the roller end is adopted.

Fig. 3 is a schematic structural view of the hot pressing mechanism of the present invention when it is a ball end.

Fig. 4 is a schematic structural view of the hot pressing mechanism of the present invention when it is a roller end.

Fig. 5 is a schematic view of the working state of the advancing hot-pressing wire-embedding device of the present invention.

Fig. 6 is a state diagram of the wire cutting of the advancing hot-pressing wire embedding device of the present invention.

Fig. 7 is a schematic structural view of the metal wire of the present invention when it is on the surface of the membrane.

Fig. 8 is a schematic structural view of the metal wire pressed into the film body according to the present invention.

Fig. 9 is a schematic structural view of the metal wire of the present invention after completely entering the membrane.

In the figure, 100, mounting plate; 210. a vacuum platform; 220. positioning pins; 310. a motor; 320. a take-up reel; 330. a guide roller; 340. a guide tube; 350. a guide ring; 410. a fixed seat; 420. a heat-conducting column; 430. a heating body; 440. a ball end; 450. a floating seat; 460. an elastic member; 470. a shaft sleeve; 480. a roller seat; 490. a movable shaft; 4110. the end of the roller; 510. a displacement cylinder; 520. a clamping jaw cylinder; 530. a blade; 600. a metal wire; 700. a membrane body.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

As shown in fig. 1, 2, 3, 4, 5, 6, 7, 8, and 9, a progressive hot-pressing wire embedding device includes: a moving mechanism (not shown), a bottom plate (not shown), a wire feeding mechanism (not shown), and a hot pressing mechanism (not shown), which can embed the metal wire 600 into the membrane or the membrane 700, and automatically hot press the metal wire 600 at the same time, so that the metal wire 600 completely enters the membrane 700, thereby improving the quality of the product and preventing the metal wire 600 from falling off.

In the prior art, the metal wire 600 and the conductor wire are required to be arranged on the transparent film body 700 so as to form a conductive film or a heat conducting film, at present, when the metal wire 600 is embedded, a method of adhesion or gluing is generally adopted, and the metal wire 600 is pressed into a groove which is preset on the film body 700 in a pressurizing mode, but the phenomenon that the metal wire 600 falls off after a long time.

In order to solve the above problems, it is particularly provided a method capable of automatically performing wire distribution according to design and then hot-pressing the wire 600 into the film body 700; the hot-pressing wire embedding device can automatically embed the metal wire 600 into the film body 700, and simultaneously hot-press the transparent film body 700 with the wire arranged, so that the metal wire 600 can completely enter the film body 700, and the metal wire 600 is not easy to separate from the film body 700.

Specifically, the motion mechanism is a mechanical arm or a robot; the movement mechanism can move according to a track set by a metal wire, and in an actual structure, the movement mechanism is set to be a six-axis mechanical arm because the track has a straight line, an arc and an irregular curve; the motion mechanism can drive the whole structure to move.

The mounting plate 100 is connected with the motion mechanism, and the motion mechanism can drive the mounting plate 100 to move; preferably, the mounting plate 100 is a vertical plate structure, and is fixed with the moving mechanism, so that the moving mechanism can drive the cutting mechanism, the wire feeding mechanism, and the hot-pressing mechanism on the mounting plate 100 to move.

A bottom plate located below the mounting plate 100, the bottom plate being used for placing a membrane body 700; preferably, the bottom plate is located below the mounting plate and is used for carrying the membrane body 700, and in brief, the membrane body 700 can be fixed on the bottom plate for processing; the base plate remains relatively fixed so the wire feeder and the heat press can be moved relative to the base plate by the mounting plate 100.

A wire feeder connected to the mounting plate 100, the wire feeder being configured to feed a wire 600 to the film body 700 on the base plate; preferably, the moving mechanism can drive the wire feeding mechanism to travel through the mounting plate 100, which can automatically supply the wires 600, and simultaneously arrange the wires 600 on the film body 700 according to a desired track through the cooperation of the hot-press mechanism.

And the hot-pressing mechanism is connected with the mounting plate 100 and is used for hot-pressing the metal wire 600 into the film body 700. Preferably, the moving mechanism can drive the hot-pressing mechanism to travel through the mounting plate 100, when the wire feeding mechanism arranges the metal wire 600 on the film body 700, the film body 700 is heated and melted because the hot-pressing mechanism acts on the contact point of the metal wire 600 and the film body 700, the metal wire 600 can directly enter the film body 700, and after the hot-pressing mechanism travels, the film body 700 at the position is cooled to reach the state that the transparent film body 700 wraps the metal wire 600.

As shown in fig. 1, 2, 3, 4, 5, and 6, in addition to the above embodiments, the cutting device further includes a cutting mechanism (not shown), which is connected to the mounting plate 100 and is configured to cut the wire 600 fed by the wire feeder.

Preferably, the cutting mechanism is capable of cutting the wire 600 after the completion of the wire embedding, and the wire 600 is pulled after the cutting so as to always keep the wire 600 right below the hot press mechanism before the next product is processed.

As shown in fig. 1, 2, and 3, based on the above embodiment, the wire feeder includes a motor 310, a take-up reel 320, a guide roller 330, and a guide tube 340, and the motor 310, the guide roller 330, and the guide tube 340 are all fixedly connected to the mounting plate 100.

The motor 310 is fixed to the back of the mounting plate 100, the rotating shaft of the motor 310 penetrates through the mounting plate 100, the guide roller 330 and the guide tube 340 are used for guiding the wire 600, and the winding roll 320 is a structure for accommodating the wire 600, can release the wire 600, and is guided to the front of the hot-pressing mechanism through the guide roller 330 and the guide tube 340.

It is noted that the guide tube 340 has a slightly larger caliber than the wire 600, and the exit of the guide tube 340 is near the lower end of the thermal compression mechanism.

The winding roll 320 is connected to the motor 310, and the wire 600 is wound around the winding roll 320 and sequentially passes through the guide roller 330 and the guide tube 340.

Preferably, when the motor 310 rotates, the winding roll 320 can be driven to rotate, so as to release the wire 600, and the wire 600 passes through the guide roller 330, passes through the guide tube 340 and is guided onto the film body 700; in addition, since the moving mechanism can drive the hot-pressing mechanism on the mounting plate 100 to move along the set track and press the wire 600 into the film body 700, the wire 600 can be arranged in a designed pattern.

As shown in fig. 1 and 3, based on the above embodiment, the wire feeder further includes a guide ring 350, the guide ring 350 is fixedly connected to the mounting plate 100, and the guide ring 350 is located between the guide roller 330 and the wire take-up reel 320.

Preferably, there is a guide ring 350 between the first guide roller 330 and the winding roll 320, and the wire 600 passes through the guide ring 350 from the winding roll 320 first, so that the following advantages are provided: when the width of the winding roll 320 is too large, the direction of the metal wire 600 can be guided preliminarily, and the phenomenon that the transmission is affected (possibly, the winding roll 320 and the adjacent first guide roller 350 are scratched to extend to cause blockage or wire falling) due to an excessively large included angle is prevented.

As shown in fig. 1, 3, 5, and 6, in addition to the above embodiments, the hot press mechanism includes a fixing base 410, a heat conducting pillar 420, a heating body 430, and a ball end 440, the fixing base 410 is connected to the mounting plate 100, the heat conducting pillar 420 is connected to the fixing base 410, the heating body 430 is inserted into the heat conducting pillar 420, and the ball end 440 is connected to the heat conducting pillar 420 and faces the bottom plate.

Preferably, the hot pressing mechanism may be configured in different structures, in this embodiment, the hot pressing mechanism is in a ball end 440 structure, that is, the hot pressing mechanism heats and buries the metal wire 600 through the ball end 440, and the heated ball end 440 can melt the surface of the film body 700, so that the metal wire 600 directly enters the film body 700; in short, the ball tip 440 contacts the membrane body 700 mainly through the balls.

Preferably, the fixing base 410 is fixed on the mounting plate, the heat-conducting post 420 can be connected to the fixing base 410, the heating body 430 is inserted into the heat-conducting post 420 and causes the heat-conducting post 420 to generate heat, the ball end 440 is fixed at the lower end of the heat-conducting post 420, the heat-conducting post 420 can heat the ball end 440, so that the ball end 440 can melt the film body 700 when contacting the film body 700; in addition, the heat conductive pillar 420 is made of copper, so that it is possible to rapidly heat and better transfer heat, and a thermocouple for detecting temperature may be further provided on the heat conductive pillar 420.

The mounting plate 100 can drive the ball end 440 to move along the track of the wire 600 through the fixing base 410 and the heat-conducting column 420, so that the wire 600 can be completely embedded in the film body 700 when the ball end 440 travels on the film body 700.

As shown in fig. 1, 3, 5, and 6, on the basis of the above embodiments, the thermal pressing mechanism further includes a floating seat 450 and an elastic member 460, the fixing seat 410 is provided with a shaft sleeve 470, the heat conducting column 420 is movably inserted into the shaft sleeve 470, the floating seat 450 is connected with the heat conducting column 420, and two ends of the elastic member 460 are respectively connected with the floating seat 450 and the fixing seat 410.

Preferably, since the fixing base 410 is provided with the shaft sleeve 470, the heat conducting pillar 420 can be inserted into the shaft sleeve 470 to move up and down, the floating base 450 is located above the fixing base 410, the ball end 440 is fixed at the lowest end of the heat conducting pillar 420, and the heating body 430 penetrates through the middle of the heat conducting pillar 420, so that the heat conducting pillar 420 can transfer heat to the ball end 440 below, the floating base 450 and the heat conducting pillar 420 are fixed together, the elastic member 460 can be a spring, and the elastic member 460 can upwards push the floating base 450, thereby providing upward elastic force for the heat conducting pillar 420 and the ball end 440.

It should be noted that the floating seat 450 and the elastic member 460 can make the ball end 440 form a floating structure, the ball end 440 travels on the membrane 700, and in order to reduce the influence of the motion mechanism and the floor flatness, the ball end 440 needs to slightly float up and down; since the overall weight of the ball end 440 is relatively large, and the contact area between the ball end 440 and the transparent film 700 is small, the single-point pressure and temperature may be too high, which may cause the film 700 to deform, the floating seat 450 and the elastic member 460 need to be increased, and the floating seat 450 is pushed upward by the spring to offset a portion of the overall weight, so as to reduce the pressure of the ball end 440 on the film 700.

Specifically, in order to make the ball end 440 have a stable thermal pressure, especially, a floating seat 450 is disposed above the fixed seat 410, then the floating seat 450 is fixed with the heat conducting pillar 420, and an elastic member 460 is disposed between the floating seat 450 and the fixed seat 410, since the ball end 440 moves the heat conducting pillar 420 downward, the elastic member 460 is compressed, and at this time, the elastic force generated by the elastic member 460 can push the floating seat 450 upward, thereby offsetting a part of the gravity of the ball end 440 and the heat conducting pillar 420.

As shown in fig. 1, 2 and 4, on the basis of the above embodiments, the hot pressing mechanism includes a fixing base 410, a roller base 480, a heating body 430 and a roller end 4110, the fixing base 410 is connected to the mounting plate 100, the roller base 480 is connected to the fixing base 410, the roller end 4110 is connected to the roller base 480 and faces the base plate, and the heating body 430 is inserted into the roller end 4110.

Preferably, the hot pressing mechanism can set up different structures, in this embodiment, the hot pressing mechanism is roller end 4110 structure, the hot pressing mechanism heats and buries the pressure wire 600 through roller end 4110 promptly, roller end 4110 after the heating presses and can melt the membrane body 700 surface behind the membrane body 700, thereby make the wire 600 directly enter into in the membrane body 700, in brief, roller end 4110 contacts the membrane body 700 through roller-shaped structure, compare ball end 440, roller end 4110 has a wider contact surface, the scope of action is bigger, has the balanced effect of hot pressing.

Preferably, the fixing seat 410 is fixed on the mounting plate, the roller seat 480 is connected to the fixing seat 410, the heating body 430 penetrates through the roller seat 480 and then penetrates into the roller end 4110, the heating body 430 can directly heat the roller end 4110, and the roller end 4110 can melt the film body 700 when contacting the film body 700; in addition, roller end 4110 is made of copper, so that heat can be quickly heated and transferred better, and a thermocouple for detecting temperature can be further arranged on roller end 4110.

The mounting plate 100 can drive the roller end 4110 to move along the track of the wire 600 through the fixing seat 410 and the roller seat 480, so that the wire 600 can be completely embedded into the film body 700 when the roller end 4110 travels on the film body 700.

It should be noted here that the roller end 4110 and the ball end 440 can smoothly travel on the surface of the film body 700, and the structure of the roller end 4110 is greatly different from that of the ball end 440, specifically: the roller end 4110 can be heated on the basis of a peripheral insulation structure, namely, the heating body 430 is directly inserted into the roller end 4110, so that personnel can be effectively prevented from being scalded; for the ball end 440 structure, the heat generating area is larger, and the heat conducting volume of the roller end 4110 is relatively smaller, so that the required heat is less, and therefore, the roller end 4110 can maintain the temperature more easily.

As shown in fig. 1, 2 and 4, on the basis of the above embodiment, the hot pressing mechanism further includes an elastic member 460, the roller seat 480 is provided with a movable shaft 490, the fixing seat 410 is provided with a shaft sleeve 470, the movable shaft 490 is movably inserted into the shaft sleeve 470, and two ends of the elastic member 460 are respectively connected to the roller seat 480 and the fixing seat 410.

Preferably, since the fixing base 410 is provided with the shaft sleeve 470, the movable shaft 490 can be inserted into the shaft sleeve 470 to move up and down, and it should be noted that the roller base 480 is located below the fixing base 410, and the heating body 430 is directly inserted into the roller end 4110, so that the heating body 430 can transfer heat to the roller end 4110.

The resilient member 460 may be a spring, and the resilient member 460 may be capable of pushing the roller seat 480 downward, thereby applying a downward resilient force to the roller tip 4110.

Preferably, the movable shaft 490 has an inverted T-shaped structure, a disc-shaped end at the lower end thereof is fixedly connected to the roller seat 480, and a shaft body structure at the upper end thereof is movably inserted into the shaft sleeve 470, and since the movable shaft 490 is a part of the roller seat 480, in a practical structure, the elastic member 460 is actually abutted against the disc-shaped end of the movable shaft 490.

It should be noted that the roller seat 480 and the elastic member 460 can make the roller end 4110 form a floating structure, the roller end 4110 travels on the film body 700, and the roller end 4110 needs to slightly float up and down in order to reduce the influence of the motion mechanism and the floor flatness.

Since the contact area between the roller end 4110 and the film body 700 is relatively large, and there may be a situation of insufficient pressure, such that the roller end 4110 always moves on the surface of the film body 700 and the wire 600 cannot be pressed into the film body 700, the elastic member 460 needs to be added, and the elastic member 460 pushes the roller seat 480 and the roller end 4110 downward, so as to increase the pressure of the roller end 4110 on the film body 700, and enable the wire 600 to be pressed into the film body 700.

As shown in fig. 1, 2, 3, 4 and 6, in addition to the above embodiment, the cutting mechanism includes a displacement cylinder 510, a jaw cylinder 520 and a blade 530, the displacement cylinder 510 is connected to the mounting plate 100, the jaw cylinder 520 is connected to a piston rod of the displacement cylinder 510, and the blade 530 is connected to the jaw cylinder 520 and is used for cutting the wire 600.

Preferably, the piston rod of the displacement cylinder 510 extends out to drive the clamping jaw cylinder 520 to approach the bottom plate, and the clamping jaw of the clamping jaw cylinder 520 is provided with a blade 530, and the blade 530 can cut off the metal wire 600; and the clamping part of the clamping jaw is serrated, so that the metal wire 600 can be clamped while the metal wire 600 is sheared. The ball end 440 or the rear end of the roller end 4110 is also provided with a limiting groove, so that the metal wire 600 can be always kept in the limiting groove before the next product is processed, and the metal wire 600 keeps a fixed trend and cannot be separated from the discharging mechanism by forming a coplanar relationship through the conduit, the hot pressing head and the limiting groove.

It should be noted that, in the actual working process, in the state to be processed, the hot-pressing mechanism is not in contact with the film body 700, the displacement cylinder 510 retracts, and the clamping jaw cylinder 520 clamps (the clamping jaw starts to release at the roller end 4110 or the ball end 440 at the same time, so as to ensure that the starting point is pressed in); and (3) processing state: the roller contacts with the membrane, the displacement cylinder 510 retracts, and the clamping jaw cylinder 520 loosens; and (3) processing completion state: the roller head 4110 and the ball head 440 are lifted, the displacement cylinder 510 is extended, and the gripper cylinder 520 grips and shears the wire 600.

As shown in fig. 1 and 3, on the basis of the above embodiment, the bottom plate includes a vacuum platform 210 and a positioning pin 220, the vacuum platform 210 is used for sucking the film body 700, the positioning pin 220 is inserted into the vacuum platform 210, and when a positioning hole is preset on the film body 700, the positioning pin 220 is used for passing through the film body 700.

Preferably, the vacuum platform 210 has a vacuum chuck, so that the film body 700 or the film sheet can be sucked, the film sheet is prevented from being warped and bent as a whole due to local heating in the processing process, the film body 700 can be positioned on the vacuum platform 210 by the positioning pin 220, and the film body 700 is firmly fixed by the suction force of the vacuum platform 210.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (10)

1. A marching type hot-pressing wire embedding device is characterized by comprising:

the movement mechanism is provided with six mechanical arms;

the mounting plate is connected with the motion mechanism, and the motion mechanism can drive the mounting plate to move;

the bottom plate is positioned below the mounting plate and used for placing a membrane body;

the wire feeding mechanism is connected with the mounting plate and is used for conveying metal wires to the film body on the bottom plate;

and the hot pressing mechanism is connected with the mounting plate and is used for hot pressing the metal wires into the membrane body.

2. A traveling hot-pressing wire-burying device as claimed in claim 1, wherein: the cutting mechanism is connected with the mounting plate and is used for cutting off the metal wire conveyed by the wire feeding mechanism.

3. A traveling hot-pressing wire-burying device as claimed in claim 1, wherein: wire feeding mechanism includes motor, take-up reel, guide roller and stand pipe, the motor guide roller and the stand pipe all with mounting panel fixed connection, the take-up reel with the motor is connected, and the wire is in around rolling up on the take-up reel and passing in proper order guide roller and the stand pipe.

4. A traveling hot-pressing wire burying device as recited in claim 3, wherein: the wire feeding mechanism further comprises a guide ring, the guide ring is fixedly connected with the mounting plate, and the guide ring is located between the guide roller and the wire coiling disc.

5. A traveling hot-pressing wire-burying device as claimed in claim 1, wherein: the hot-pressing mechanism comprises a fixing seat, a heat-conducting column, a heating body and a ball end, the fixing seat is connected with the mounting plate, the heat-conducting column is connected with the fixing seat, the heating body is inserted into the heat-conducting column, and the ball end is connected with the heat-conducting column and faces the bottom plate.

6. A traveling hot-pressing wire burying device as recited in claim 5, wherein: the hot pressing mechanism further comprises a floating seat and an elastic piece, the fixed seat is provided with a shaft sleeve, the heat conducting column is movably arranged in the shaft sleeve in a penetrating mode, the floating seat is connected with the heat conducting column, and two ends of the elastic piece are respectively connected with the floating seat and the fixed seat.

7. A traveling hot-pressing wire-burying device as claimed in claim 1, wherein: the hot pressing mechanism comprises a fixed seat, a roller seat, a heating body and a roller end, the fixed seat is connected with the mounting plate, the roller seat is connected with the fixed seat, the roller end is connected with the roller seat and faces the bottom plate, and the heating body is inserted in the roller end.

8. A traveling hot-pressing wire burying device as recited in claim 7, wherein: the hot pressing mechanism further comprises an elastic piece, the roller seat is provided with a movable shaft, the fixed seat is provided with a shaft sleeve, the movable shaft is movably arranged in the shaft sleeve in a penetrating mode, and two ends of the elastic piece are connected with the roller seat and the fixed seat respectively.

9. A traveling hot-pressing wire burying device as recited in claim 2, wherein: the shutdown mechanism includes displacement cylinder, clamping jaw cylinder and blade, displacement cylinder with the mounting panel is connected, clamping jaw cylinder with displacement cylinder's piston rod is connected, the blade with clamping jaw cylinder is connected and is used for cutting off the wire.

10. A traveling hot-pressing wire-burying device as claimed in claim 1, wherein: the bottom plate comprises a vacuum platform and a positioning pin, the vacuum platform is used for sucking the membrane body, the positioning pin penetrates through the vacuum platform, and the positioning pin is used for penetrating through the membrane body.

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