CN215453808U - NFC laminating production facility - Google Patents

Abstract

The utility model discloses NFC laminating production equipment. This NFC laminating production facility sets gradually the soft board feed mechanism along the production material shifts the direction of advance, paste ferrite mechanism, rubberizing mechanism, RF accredited testing organization and tectorial membrane mechanism, and act as go-between through connection by the backward flow between the station that each mechanism corresponds, the backward flow is acted as go-between and is put and is carried the material tool, the soft board is by soft board feed mechanism material loading to carrying behind the material tool, can transport to each station and paste the ferrite by the mechanism that corresponds on each station under the assembly line transport that the backward flow was acted as go-between, paste blue glue, RF test and tectorial membrane, the product after the shaping can be carried out the unloading by the unloading subassembly that unloading station department set up at last, realize the pipelined automated production operation of NFC chip, greatly improve the productivity of NFC chip, and guarantee the production yield of product.

Description

NFC laminating production facility

Technical Field

The utility model relates to the technical field of NFC chip production equipment, in particular to NFC laminating production equipment.

Background

An NFC (near Field communication) chip is an important component of NFC technology, and has a communication function and a certain computing power, and some NFC chip products even contain an encryption logic circuit and an encryption/decryption module.

With the wider application range of the NFC technology in electronic devices such as mobile phones and the like and the increase in the demand of corresponding electronic devices, higher and higher requirements are also put forward on the production efficiency of NFC chips. In the production of the NFC chip, the processes of feeding an FPC Board (Flexible Printed Circuit Board), attaching ferrite, attaching blue gel, laminating and the like are included, wherein the quality detection of the product and the like are also involved, and the overall process is relatively complicated. Therefore, the assembly line type automatic production of the NFC chip is realized, the productivity of the NFC chip is greatly improved, and the large-scale market demand on the NFC chip is met.

SUMMERY OF THE UTILITY MODEL

The utility model provides an NFC laminating production device, in particular to a production line type NFC automatic laminating production device, aiming at realizing production line type automatic production of NFC chips and meeting the capacity requirement of the NFC chips.

The purpose of the utility model is realized by the following technical scheme.

An NFC laminating production device sequentially comprises a soft board loading position, a ferrite pasting position, a rubberizing position, an RF testing position and a film laminating position along the moving direction of production materials, wherein a soft board loading mechanism, a ferrite pasting mechanism, a rubberizing mechanism, an RF testing mechanism and a film laminating mechanism are correspondingly arranged on each position; the soft board loading mechanism can be used for loading the soft board, and the ferrite pasting mechanism, the adhesive pasting mechanism, the RF testing mechanism and the film coating mechanism can be used for sequentially pasting ferrite, adhesive pasting, RF testing and film coating on the loaded soft board;

the soft board loading position, the ferrite pasting station, the adhesive pasting station, the RF testing station and the film coating station are in through connection through a backflow pull wire; and a material loading jig is arranged on the backflow stay wire, and the material loading jig can move forwards on the backflow stay wire.

In a preferred embodiment, the soft board feeding mechanism comprises a soft board fine positioning frame, a feeding jig lifting frame and a feeding jig carrying hand; the feeding jig lifting frame is provided with a feeding lifting cylinder capable of jacking the loading jig, and the feeding jig lifting frame can move in a lifting manner; the feeding jig lifting frame is connected with the feeding end of the backflow stay wire, and the feeding jig carrying hand can transfer the soft plate material from the soft plate fine positioning frame to the material carrying jig of the feeding jig lifting frame.

In a more preferred embodiment, the upper jig carrying hand is driven by a corresponding upper jig cylinder to move.

In a more preferred embodiment, a soft plate stacking rack is arranged on the feeding side of the soft plate fine positioning rack, and a membrane stacking rack is arranged on one side of the soft plate stacking rack; and a soft board carrying hand is arranged between the soft board stacking rack and the soft board fine positioning rack, and a membrane carrying hand is arranged between the membrane stacking rack and the soft board stacking rack.

In a more preferred embodiment, the flexible board handling hands are driven by corresponding flexible board handling cylinders to move; and/or the diaphragm taking carrying hand is driven by the corresponding diaphragm taking cylinder to move.

In a preferred embodiment, the ferrite attaching mechanism comprises a ferrite stripping feeder, a ferrite suction nozzle and a ferrite attaching moving module;

the ferrite stripping flight reach is arranged on the outer side of the backflow stay wire; the ferrite paste material moving module is in transmission connection with the ferrite suction nozzle and can drive the ferrite suction nozzle to move back and forth to take and paste materials between the ferrite stripping flying reach and the backflow pull line.

In a preferred embodiment, the adhesive applying mechanism comprises a blue adhesive stripping feeder, a blue adhesive suction nozzle and a blue adhesive applying moving module;

the blue gel stripping flight reach is arranged on the outer side of the backflow pull wire; the blue glue paste moving module is in transmission connection with the blue glue suction nozzle and can drive the blue glue suction nozzle to move back and forth to take and paste materials between the blue glue stripping flying reach and the backflow pull line.

More preferably, the ferrite stripping flying reach and the blue glue stripping flying reach both comprise a flying reach unwinding roller, a flying reach passing roller, a stripping platform and a flying reach winding roller which are sequentially arranged along the stripping feeding direction, the feeding side of the stripping platform is correspondingly provided with a retreating platform, and the retreating platform can be moved to be close to or far away from the stripping platform.

In a preferred embodiment, the RF testing mechanism includes a testing loading platform, a testing material taking suction cup, a testing material taking moving module and an RF testing assembly;

the test material taking moving module is in transmission connection with the test material taking sucker and can drive the test material taking sucker to move back and forth between the backflow pull line and the test material loading platform to carry out test material taking, test material loading and test material unloading; and the RF test assembly is provided with an RF test probe which can move close to the test material loading platform and detect the material on the test material loading platform.

In a more preferred embodiment, the RF test probe is disposed on an RF test circuit board and connected to an RF tester by an RF test connection.

In a more preferred embodiment, the RF testing mechanism is provided with an RF testing bad mark module, optionally including a coding machine, and the RF testing bad mark module can mark the tested bad product.

In a more preferred embodiment, the test loading platform can move horizontally and longitudinally and move up and down under the driving of the horizontal transverse driving piece, the horizontal longitudinal driving piece and the vertical driving piece respectively.

In a preferred embodiment, the film laminating mechanism comprises a diaphragm unwinding assembly, a diaphragm cutting assembly, a film pulling assembly and a film taking assembly which are sequentially arranged along the unwinding feeding advancing direction;

the membrane cutting assembly can cut the membrane stretched by the membrane stretching assembly; the membrane taking assembly comprises a membrane suction plate and a membrane covering moving module; after the membrane unreeled by the membrane unreeling component is pulled to be membrane by the membrane pulling component, the membrane suction plate can be driven by the membrane covering moving module to move to be positioned between the membrane pulling component and the membrane cutting component, the membrane stretched by the membrane pulling component is sucked and continuously adsorbed after being cut to be membrane, and then the membrane covering moving module drives the belt to carry out membrane covering transfer with the adsorbed membrane.

In a more preferred embodiment, the membrane unwinding assembly comprises a membrane unwinding roller and a membrane unwinding roller.

In a more preferred embodiment, the membrane cutting assembly includes a cutting knife and a pressing block; the film pressing block is driven by the film pressing driving piece to move close to and press the film belt which is unreeled, the cutting knife is arranged at the discharge end of the film pressing block, and the cutting knife is driven by the film pressing driving piece to be aligned with the discharge end of the film pressing block to roll the diaphragm out for transverse cutting.

More preferably, the film drawing assembly comprises an upper film drawing clamping plate, a lower film drawing clamping plate and a clamping driving piece; the upper film-drawing clamping plate is hinged with the lower film-drawing clamping plate and can be driven by the clamping driving piece to open and close.

In a preferred embodiment, in the NFC laminating production apparatus described in any one of the above embodiments, a manual detection position is provided between the RF testing station and the laminating station, and a manual detection material taking assembly is correspondingly provided; the manual detection material taking assembly comprises a detection material taking sucker and a detection material taking moving module which can drive the detection material taking sucker to move;

and/or a blanking station is arranged on one side of the film covering station, and a blanking assembly is correspondingly arranged on one side of the film covering station; the blanking assembly comprises a blanking sucker and a blanking moving module which can drive the blanking sucker to move;

and/or a hot-pressing rolling mechanism is arranged between the rubberizing station and the RF testing station, and comprises a hot-pressing roller.

More preferably, a blanking jig lifting frame is connected between the blanking station and the backflow bracing wire.

Compared with the prior art, the utility model has the following advantages and beneficial effects:

according to the NFC laminating production equipment, the soft board feeding mechanism, the ferrite pasting mechanism, the adhesive pasting mechanism and the film laminating mechanism are sequentially arranged along the moving direction of production materials, the stations corresponding to the mechanisms are connected in a through mode through the backflow pull wires, after the soft boards are fed by the soft board feeding mechanism, the soft boards can be conveyed to the stations on the assembly line of the backflow pull wires and are pasted with the ferrite, the blue glue and the film by the corresponding mechanisms on the stations, the molded products can be finally discharged by the discharging assembly arranged at the discharging station, the assembly line type automatic production operation of NFC chips is achieved, and the production capacity of the NFC chips is greatly improved.

In addition, be provided with RF test station between rubberizing station and tectorial membrane station to the corresponding RF accredited testing organization that sets up can carry out the RF test to the product after the rubberizing, and the defective products of test can be followed the backward flow and acted as go-between and shifted out to the manual work and detect the position and carry out the manual work and detect, thereby greatly improve product detection efficiency, ensure the production yield of product.

Drawings

Fig. 1 is a schematic perspective view of NFC bonding production equipment in an embodiment of the present invention;

fig. 2 is a schematic top view of an NFC bonding production apparatus according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a soft board feeding mechanism;

FIG. 4 is a schematic view of the overall structure of the ferrite attaching mechanism;

FIG. 5 is a schematic view of a partial structure of a ferrite attaching mechanism;

FIG. 6 is a schematic structural view of a ferrite stripping Feda;

FIG. 7 is a schematic diagram of the structure of the RF test mechanism;

FIG. 8 is a schematic diagram of an RF test assembly;

FIG. 9 is a schematic structural view of a material taking assembly and a material discharging assembly for manual detection;

FIG. 10 is a schematic view of the overall structure of the film covering mechanism;

FIG. 11 is a partial schematic view of the film covering mechanism;

FIG. 12 is a schematic structural view of a film drawing assembly;

FIG. 13 is a schematic view showing a partial structure of a membrane module;

the attached drawings are marked as follows: 1-a rack, 1001-a manual detection table board, 2-a reflow pull wire, 3-a material loading jig, 4-a soft board feeding mechanism, 41-a soft board fine positioning frame, 42-a feeding jig lifting frame, 43-a feeding jig carrying hand, 44-a feeding jig air cylinder, 45-a feeding lifting air cylinder, 46-a soft board stacking frame, 47-a diaphragm stacking frame, 48-a soft board taking carrying hand, 49-a soft board taking air cylinder, 410-a diaphragm taking carrying hand, 411-a diaphragm taking air cylinder, 5-a ferrite mechanism, 51-a ferrite stripping flying reach, 511-a flying reach unwinding roller, 512-a flying reach passing roller, 513-a stripping platform, 514-a flying reach winding roller, 515-a backward platform, 52-a ferrite suction nozzle, 53-a ferrite pasting moving module, 531-sticking material transverse moving module, 532-sticking material longitudinal moving module, 6-sticking mechanism, 7-RF testing mechanism, 71-testing material loading table, 72-testing material taking sucker, 73-testing material taking moving module, 74-RF testing component, 741-RF testing probe, 742-RF testing circuit board, 743-RF testing connecting line, 744-RF tester, 75-RF testing bad mark module, 76-horizontal transverse driving component, 77-horizontal longitudinal driving component, 78-vertical driving component, 8-laminating mechanism, 81-membrane unwinding component, 811-membrane unwinding roller, 812-membrane unwinding roller, 82-membrane cutting component, 821-cutting knife, 822-cutting driving component, 823-membrane pressing block and 824-membrane pressing driving component, 83-a film drawing assembly, 831-an upper film drawing clamping plate, 832-a lower film drawing clamping plate, 833-a clamping driving piece, 84-a film taking assembly, 841-a diaphragm suction plate, 842-a film taking fixed vertical plate, 843-a film covering moving module, 9-a manual detection material taking assembly, 91-a detection material taking sucker, 92-a detection material taking moving module, 10-a blanking assembly, 101-a blanking sucker, 102-a blanking moving module, 103-a blanking jig lifting frame, 104-a blanking lifting cylinder, 105-a finished product transition frame, 106-a finished product blanking frame, 11-a hot-pressing rolling mechanism and 12-a diaphragm.

Detailed Description

The technical solutions of the present invention are further described in detail below with reference to specific examples and drawings, but the scope and implementation of the present invention are not limited thereto.

In the description of the specific embodiments, it should be noted that the terms "upper", "lower", "front", "back", "left", "right", "longitudinal", "transverse", "vertical", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings or orientations or positional relationships that the products of the present invention usually place when in use, and are used for convenience of distinction and only for convenience of description and simplification of description, but do not indicate or imply that the structures or elements that are referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, are not to be construed as limiting the present invention, and are not to indicate or imply relative importance.

Unless expressly stated or limited otherwise, the terms "mounted," "disposed," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral connections; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 and 2, the NFC attachment production device of the present invention includes a rack 1, and a backflow pull line 2 is disposed on a working platform of the rack 1. Wherein, a material loading jig 3 is arranged on the backflow stay wire 2, and the material loading jig 3 can move forwards on the backflow stay wire 2. During production operation, the material body is loaded on the material loading jig 3 and the production material is transferred and moved forward under the transportation of the backflow bracing wire 2.

Transfer the direction of advance along the production material, set gradually including the soft board material loading level, paste ferrite station, rubberizing station, RF test station and tectorial membrane station on the table surface of frame 1, soft board material loading level, paste ferrite station, rubberizing station, RF test station and tectorial membrane station are acted as go-between 2 through connections by the backward flow, and year material tool 3 can be followed the backward flow and acted as go-between 2 and advance to each station in proper order, and correspond respectively on each station and be provided with soft board feed mechanism 4, paste ferrite mechanism 5, rubberizing mechanism 6, RF test mechanism 7 and tectorial membrane mechanism 8. When production operation is carried out, the soft board feeding mechanism 4 can carry out FPC soft board feeding to the material carrying jig 3 of the backflow stay wire 2, the material carrying jig 3 moves ahead on the backflow stay wire 2 to carry out material body conveying, and the ferrite pasting mechanism 5, the adhesive pasting mechanism 6, the RF testing mechanism 7 and the film covering mechanism 8 can sequentially carry out ferrite pasting, adhesive pasting, RF testing and film covering on the fed soft board in sequence respectively, so that NFC chip production is completed. Furthermore, a blanking station is arranged on one side of the film covering station, and a blanking assembly 10 is correspondingly arranged on one side of the film covering station, so that produced products can be blanked.

In a preferred embodiment, referring to fig. 3, the soft board feeding mechanism 4 includes a soft board fine positioning frame 41, a feeding jig lifting frame 42, and an upper jig carrying hand 43. Wherein, the loading jig lifting frame 42 is stacked with empty trays of loading jigs 3 to be placed, and the loading jig lifting frame 42 is provided with a loading lifting cylinder 45 capable of lifting the loading jigs 3, and further, the loading jig lifting frame 42 can move up and down; moreover, the feeding jig lifting frame 42 is connected to the feeding end of the reflow wire 2, the upper jig carrying hand 43 can transfer the soft board material from the soft board fine positioning frame 41 to the material carrying jig of the feeding jig lifting frame 42, and the upper jig carrying hand 43 is driven by the corresponding upper jig air cylinder 44 to move.

In addition, a soft board stacking rack 46 is arranged on the feeding side of the soft board fine positioning rack 41, and a membrane stacking rack 47 is arranged on one side of the soft board stacking rack 46; and soft board piling bin 46 with be provided with between the fine locating rack 41 of soft board and get soft board porter 48, get soft board porter 48 and remove by the corresponding soft board cylinder 49 drive of getting, diaphragm piling bin 47 with be provided with between the soft board piling bin 46 and get diaphragm porter 410, it removes by the corresponding diaphragm cylinder 411 drive of getting to get diaphragm porter 410.

When the flexible printed circuit board feeding mechanism 4 feeds the flexible printed circuit board, the flexible printed circuit board material is firstly manually stacked on the flexible printed circuit board stacking rack 46, the membrane taking cylinder 411 drives the membrane taking carrying hand 410 to move to the flexible printed circuit board stacking rack 46 to take away the membrane covered on the material and transfer the membrane to the membrane stacking rack 47 for recycling, the flexible printed circuit board taking cylinder 49 drives the flexible printed circuit board carrying hand 48 to move to the flexible printed circuit board stacking rack 46 to take away the flexible printed circuit board and transfer the flexible printed circuit board to the flexible printed circuit board fine positioning rack 41, the upper jig carrying hand 43 is driven by the upper jig cylinder 44 to move to the flexible printed circuit board fine positioning rack 41 to take away the placed flexible printed circuit board and transfer the flexible printed circuit board to the empty tray material carrying jig 3 of the feeding jig lifting rack 42, and the feeding material lifting cylinder 45 on the feeding jig lifting rack 42 lifts the material carrying jig 3 carrying the flexible printed circuit board to enable the material carrying jig 3 to flow into the backflow stay wire 2, so that feeding is completed. While the number of the loading jigs 3 stacked on the loading jig lifting frame 42 is continuously decreased, the loading jig lifting frame 42 is moved upward to perform height adjustment, so that the loading jig 3 positioned on the uppermost layer can smoothly flow into the return pull wire 2.

In a preferred embodiment, as shown in fig. 4 and 5, the ferrite attaching mechanism 5 includes a ferrite peeling fly 51, a ferrite suction nozzle 52, and a ferrite attaching moving module 53. Wherein the ferrite stripping booms 51 are arranged outside the reflow pull wire 2; the ferrite paste moving module 53 is in transmission connection with the ferrite suction nozzle 52, and can drive the ferrite suction nozzle 52 to move back and forth to take and paste materials between the ferrite stripping flying head 51 and the reflow wire 2.

Specifically, the ferrite material sticking moving module 53 comprises a material sticking transverse moving module 531 and a material sticking longitudinal moving module 532, the ferrite suction nozzle 52 is slidably connected with the material sticking transverse moving module 531 through a connecting plate, and the material sticking transverse moving module 531 is slidably arranged on the material sticking longitudinal moving module 532, so that the ferrite suction nozzle 52 can be driven to horizontally move transversely and horizontally longitudinally; and furthermore, a material sticking lifting cylinder and a material sticking rotating cylinder are arranged between the ferrite suction nozzle 52 and the connecting plate, so that the ferrite suction nozzle 52 can be driven to lift and rotate, and the material can be flexibly and accurately taken and stuck.

Referring to fig. 6, the ferrite stripping flying apparatus 51 includes a flying apparatus unwinding roller 511, a flying apparatus passing roller 512, a stripping platform 513 and a flying apparatus winding roller 514, which are sequentially arranged along a stripping feeding direction, a retreating platform 515 is correspondingly arranged on a feeding side of the stripping platform 513, and the retreating platform 515 is movable close to or away from the stripping platform 513. During material stripping, the material body is uncoiled by the flying winding-unwinding roller 511, passes through the flying winding-up roller 512, and enters the retreating platform 515 for material stripping, the stripped material body falls onto the material stripping platform 513, and the stripped waste material enters the flying winding-up roller 514 for winding. Further optionally, a plurality of flying rollers 512 are provided, and a belt pressing block can be arranged on the feeding side of the flying roller 512 close to the stripping platform 513 to strip the material; further, a winding pressure roller is provided outside the flying winding roller 514.

In a preferred embodiment, the rubberizing mechanism 6 is the same as the ferrite rubberizing mechanism 5, that is, the rubberizing mechanism 6 includes a blue-glue stripping feeder, a blue-glue suction nozzle and a blue-glue-rubberizing moving module, the blue-glue stripping feeder, the blue-glue suction nozzle and the blue-glue-rubberizing moving module are respectively and correspondingly arranged the same as the ferrite stripping feeder 51, the ferrite suction nozzle 52 and the ferrite rubberizing moving module 53, and the blue-glue stripping feeder is arranged outside the reflow wire 2; the blue glue paste moving module is in transmission connection with the blue glue suction nozzle and can drive the blue glue suction nozzle to move back and forth to take and paste materials between the blue glue stripping flying reach and the backflow pull wire 2.

In a preferred embodiment, after the blue glue pasting is completed, the blue glue hot pressing pasting can be performed. Referring to fig. 1 and 2 again, in a preferred embodiment, a hot-pressing and rolling mechanism 11 is disposed between the rubberizing station and the RF testing station, and the hot-pressing and rolling mechanism 11 includes a hot-pressing roller. Wherein, the hot-pressing roller is arranged on the reflow bracing wire 2 in a crossing way and can move back and forth along the reflow bracing wire 2 in a limited distance. After the blue glue is pasted on the soft board, the soft board is continuously conveyed to the next station process by the backflow stay wire 2, and the hot pressing roller of the hot pressing and rolling mechanism 11 can perform online hot pressing and rolling on the blue glue pasting semi-finished product in the conveying process, so that the stable pasting of the blue glue is ensured.

In a preferred embodiment, as shown in fig. 7, the RF testing mechanism 7 includes a test loading platform 71, a test reclaiming chuck 72, a test reclaiming moving module 73, and an RF testing assembly 74. The test material taking moving module 73 is in transmission connection with the test material taking sucker 72 and can drive the test material taking sucker 72 to move back and forth between the backflow pull line 2 and the test material loading platform 71 to perform test material taking and test material loading; an RF test probe 741 is disposed on the RF test assembly 74, and the RF test probe 741 can move close to the test material loading platform 71 and detect a material on the test material loading platform 71.

Specifically, as shown in fig. 8, the RF test probe 741 is disposed on an RF test circuit board 742 and connected to an RF tester 744 via an RF test connection line 743, the RF test assembly 74 is mounted on a support frame and provided with a test lifting cylinder capable of driving the RF test assembly 74 to press down, the RF test assembly 74 is located above the test loading platform 71, and a pin of the RF test probe 741 is connected to a pin body in a spring-retractable manner. The testing material taking moving module 73 comprises a testing material taking transverse moving module, the testing material taking sucker 72 is connected to the testing material taking transverse moving module through a connecting plate in a sliding mode, a testing material taking lifting cylinder and a testing material taking rotating cylinder are arranged between the testing material taking sucker 72 and the connecting plate, the testing material taking sucker 72 can be driven to lift and rotate, and accurate material taking and testing material placing can be flexibly controlled. Moreover, the test loading platform 71 can move horizontally and horizontally, vertically and vertically under the driving of the horizontal driving component 76, the horizontal driving component 77 and the vertical driving component 78, so as to drive the test loading platform 71 to perform precise test positioning with the RF test assembly 74.

When the RF test is performed, the test material taking moving module 73 drives the test material taking suction cup 72 to move to the position of the reflow pull wire 2 to take the product on the material loading jig 3 away and transfer the product to the test material loading table 71, after the test material loading table 71 is driven by the horizontal transverse driving element 76, the horizontal longitudinal driving element 77 and the vertical driving element 78 to perform the precise positioning of the product and the RF test probe 741 of the RF test assembly 74, the RF test probe 741 of the RF test assembly 74 moves down to contact the product and perform the RF test, and the test data is transmitted to the RF tester 744. Further, an RF testing bad mark module 75 is arranged on the RF testing mechanism 7, and optionally includes a coding machine, and the RF testing bad mark module 75 can mark the tested bad products so as to screen out the bad products.

In another preferred embodiment, please refer to fig. 2 and 9, a manual detection station is provided between the RF testing station and the laminating station, specifically, a manual detection table 1001 is provided on the working table of the rack 1 and outside the reflow wire 2, and a manual detection reclaiming assembly 9 is correspondingly provided. Wherein, artifical the detection get material subassembly 9 including detecting get material sucking disc 91, and can order about the detection that detects and get material sucking disc 91 and remove module 92, detect to get material and remove module 92 specifically including detecting and get material sideslip module, detect and get material sucking disc 91 and pass through connecting plate sliding connection on detecting and get material and remove module 92, and detect and be provided with between getting material sucking disc 91 and the connecting plate and detect and get material lift cylinder and detect and get material revolving cylinder, can order about to detect and get material sucking disc 91 and go up and down and rotate, flexible control carries out accurate detection and gets material, the blowing.

Therefore, after the RF testing mechanism 7 detects the product and marks the defective product, the product continues to move forward in the backflow stay wire 2, the detection material taking moving module 92 drives the detection material taking sucker 91 to transfer the product to the manual detection table 1001 on line, and the manual inspection is carried out, so that the product is prevented from being detected by mistake, the defective condition of the product can be known, and the production line can be fed back and adjusted.

In a preferred embodiment, as shown in fig. 10 and 11, the laminating mechanism 8 includes a membrane unwinding assembly 81, a membrane cutting assembly 82, a membrane pulling assembly 83, and a membrane taking assembly 84, which are sequentially arranged along an unwinding feeding advancing direction, and the membrane pulling assembly 83 is movably disposed on the substrate close to or far from the membrane cutting assembly 82. The membrane unreeling component 81 can unreel the membrane, the unreeled membrane is drawn by the membrane drawing component 83, the membrane cutting component 82 can cut the membrane drawn by the membrane drawing component 83, the membrane taking component 84 can fix the membrane 12 drawn by the membrane drawing component 83, and the membrane 12 is taken away and transferred to cover the product after the membrane cutting component 82 cuts the membrane 12.

Specifically, referring to fig. 9 and 10, the membrane unwinding assembly 81 includes a membrane unwinding roller 811 and a membrane unwinding roller 812, and the membrane material roll may be mounted on the membrane unwinding roller 811 and may be unwound and passed through the membrane unwinding roller 812. The diaphragm cutting assembly 82 comprises a cutting knife 821 and a film pressing block 823, the cutting knife 821 and the film pressing block 823 are specifically arranged on the front side and the rear side of the cutting vertical plate respectively, and the bottom of the cutting vertical plate is provided with a material passing hole through which the diaphragm 12 can be unreeled; the film pressing block 823 is arranged outside the feeding side of the material passing port, and is driven by a film pressing driving piece 824 to move close to and press on a film belt unreeled through the material passing port; the cutting knife 821 is arranged outside the discharging side of the material passing port and is relatively positioned at the discharging end of the film pressing block 823, and the membrane 12 which is unreeled from the material passing port and penetrates out is stretched by the membrane pulling assembly 83; and the cutting knife 821 is in transmission connection with the cutting driving member 822 through a belt and a belt pulley, and the cutting driving member 822 drives the diaphragm 12 which is unwound from the discharging end of the diaphragm pressing block 823 to be transversely cut.

Referring to fig. 12, the membrane drawing assembly 83 includes an upper membrane clamping plate 831, a lower membrane clamping plate 832 and a clamping driving member 833; the upward-pulling film clamping plate 831 is hinged with the downward-pulling film clamping plate 832 and can be driven by the clamping driving piece 833 to open and close. Wherein, lower drawing film splint 832 and press from both sides tight driving piece 833 and all set up on drawing the membrane mount pad, just the front end of going up drawing film splint 831 with the front end of lower drawing film splint 832 corresponds, the rear end of going up drawing film splint 8331 is articulated on the rear end of lower drawing film splint 832, the output of pressing from both sides tight driving piece 833 with the rear end of going up drawing film splint 831 is connected, the output of pressing from both sides tight driving piece 833 can order about when flexible the rear end tilting of going up drawing film splint 831 and drive the front end of going up drawing film splint 831 with the front end of lower drawing film splint 832 presss from both sides tightly or unclamps to realize going up drawing film splint 831 and drawing opening and shutting down between the film splint 832. When the film is drawn, after the film drawing mounting seat moves on the substrate to be close to the diaphragm cutting assembly 82, the clamping driving piece 833 drives the upper film drawing clamping plate 831 and the lower film drawing clamping plate 832 to be closed so as to clamp the diaphragm 12 extending out from the unwinding port of the diaphragm cutting assembly 82; and then the film drawing mounting seat moves on the substrate away from the diaphragm cutting assembly 82, and the film drawing of the diaphragm 12 can be completed in the moving away process.

In addition, as shown in fig. 2 and fig. 13, the film taking assembly 84 includes a membrane suction plate 841 and a film moving module 843, the film moving module 843 specifically includes a film traversing module, the membrane suction plate 841 is connected with the film moving module 843 through a film taking fixing vertical plate 842, and a film coating lifting cylinder and a film coating rotating cylinder are arranged between the diaphragm suction plate 841 and the film taking fixed vertical plate 842, the diaphragm suction plate 841 can be driven to lift and rotate, the accurate film taking and film covering can be flexibly controlled, after the membrane 12 unreeled by the membrane unreeling assembly 81 is drawn by the membrane drawing assembly 83, the membrane suction plate 841 can be driven by the membrane covering moving module 843 to move to a position between the membrane drawing assembly 83 and the membrane cutting assembly 82, the membrane 12 stretched by the membrane stretching assembly 83 is sucked, the membrane 12 is continuously adsorbed after membrane cutting, and the membrane laminating moving module 843 drives the membrane 12 with the adsorption to perform membrane laminating transfer.

In another preferred embodiment, referring to fig. 9 again, the blanking assembly 10 includes a blanking suction cup 101 and a blanking moving module 102 for driving the blanking suction cup 101 to move. The blanking moving module 102 specifically comprises a blanking traversing module, and the blanking sucker 101 is connected to the blanking traversing module through a connecting plate; in addition, a finished product transition conversion frame 105 and a finished product blanking frame 106 are also arranged on the blanking station; a blanking jig lifting frame 103 is connected between the blanking station and the backflow stay wire 2, the blanking jig lifting frame 103 is specifically positioned between the blanking end of the backflow stay wire 2 and the finished product transition conversion frame 105 along the advancing direction of material body transfer, a blanking lifting cylinder 104 capable of lifting the material loading jig 3 is arranged on the blanking jig lifting frame 103, and the blanking jig lifting frame 103 can move up and down; in addition, a lower jig carrying hand is arranged between the feeding jig lifting frame 103 and the finished product transition conversion frame 105, the lower jig carrying hand can be driven by the lower jig cylinder to move between the feeding jig lifting frame 103 and the finished product transition conversion frame 105, the finished product discharging frame 106 corresponds to the film coating station, and the film coating moving module 843 can drive the diaphragm suction plate 841 to reciprocate between the film coating station and the finished product discharging frame 106.

When laminating and blanking are carried out, the blanking jig lifting frame 103 can move upwards to carry out height adjustment, so that the material carrying jig 3 of the backflow stay wire 2 can smoothly flow into the blanking jig lifting frame 103, the material carrying jig 3 on the backflow stay wire 2 carries a finished product and falls onto the blanking jig lifting frame 103, and then the lower jig carrying hand is driven by the blanking cylinder to move to the blanking jig lifting frame 103 to grab the product and continuously transfer the product onto the finished product transition conversion frame 105; the discharging suction cups 101 can be driven by the discharging moving module 102 to move to the finished product transition rack 105 to grab the finished product, and then the finished product is transferred to the finished product discharging rack 106. On the finished product blanking frame 106, the film covering moving module 843 can drive the diaphragm suction plate 841 for sucking the diaphragm to cover the diaphragm 12 on the finished product, and the finished product after film covering can be blanked.

The above embodiments are merely preferred embodiments of the present invention, and the technical solutions of the present invention are described in further detail, but the above descriptions are exemplary, not exhaustive, and are not limited to the disclosed embodiments, the scope and implementation of the present invention are not limited thereto, and any changes, combinations, deletions, substitutions or modifications that do not depart from the spirit and principle of the present invention are included in the scope of the present invention.

Claims (10)

1. An NFC laminating production device is characterized by comprising a soft board loading position, a ferrite pasting position, a rubberizing position, an RF testing position and a film covering position in sequence along the forward direction of production material transfer, wherein a soft board loading mechanism, a ferrite pasting mechanism, a rubberizing mechanism, an RF testing mechanism and a film covering mechanism are correspondingly arranged on each position respectively; the soft board loading mechanism can be used for loading the soft board, and the ferrite pasting mechanism, the adhesive pasting mechanism, the RF testing mechanism and the film coating mechanism can be used for sequentially pasting ferrite, adhesive pasting, RF testing and film coating on the loaded soft board;

the soft board loading position, the ferrite pasting station, the adhesive pasting station, the RF testing station and the film coating station are in through connection through a backflow pull wire; and a material loading jig is arranged on the backflow stay wire, and the material loading jig can move forwards on the backflow stay wire.

2. The NFC laminating production equipment of claim 1, wherein the soft board feeding mechanism comprises a soft board fine positioning frame, a feeding jig lifting frame and a feeding jig carrying hand; the feeding jig lifting frame is provided with a feeding lifting cylinder capable of jacking the loading jig, and the feeding jig lifting frame can move in a lifting manner; the feeding jig lifting frame is connected with the feeding end of the backflow stay wire, and the feeding jig carrying hand can transfer the soft plate material from the soft plate fine positioning frame to the material carrying jig of the feeding jig lifting frame.

3. The NFC laminating production equipment according to claim 2, wherein a soft board stacking rack is arranged on a feeding side of the soft board fine positioning rack, and a diaphragm stacking rack is arranged on one side of the soft board stacking rack; and a soft board carrying hand is arranged between the soft board stacking rack and the soft board fine positioning rack, and a membrane carrying hand is arranged between the membrane stacking rack and the soft board stacking rack.

4. The NFC laminating production equipment of claim 1, wherein the ferrite laminating mechanism comprises a ferrite stripping booms, a ferrite suction nozzle and a ferrite laminating moving module;

the ferrite stripping flight reach is arranged on the outer side of the backflow stay wire; the ferrite paste material moving module is in transmission connection with the ferrite suction nozzle and can drive the ferrite suction nozzle to move back and forth to take and paste materials between the ferrite stripping flying reach and the backflow pull line.

5. The NFC laminating production equipment of claim 1, wherein the adhesive attaching mechanism comprises a blue adhesive stripping feeder, a blue adhesive suction nozzle and a blue adhesive attaching moving module;

the blue gel stripping flight reach is arranged on the outer side of the backflow pull wire; the blue glue paste moving module is in transmission connection with the blue glue suction nozzle and can drive the blue glue suction nozzle to move back and forth to take and paste materials between the blue glue stripping flying reach and the backflow pull line.

6. The NFC laminating production equipment of claim 1, wherein the RF testing mechanism comprises a test material loading platform, a test material taking sucker, a test material taking moving module and an RF testing component;

the test material taking moving module is in transmission connection with the test material taking sucker and can drive the test material taking sucker to move back and forth between the backflow pull line and the test material loading platform to carry out test material taking, test material loading and test material unloading; and the RF test assembly is provided with an RF test probe which can move close to the test material loading platform and detect the material on the test material loading platform.

7. The NFC laminating production equipment of claim 6, wherein the test material loading platform can move horizontally and horizontally, move horizontally and longitudinally, and move up and down under the driving of the horizontal transverse driving member, the horizontal longitudinal driving member, and the vertical driving member, respectively.

8. The NFC laminating production equipment according to claim 1, wherein the film laminating mechanism comprises a membrane unwinding assembly, a membrane cutting assembly, a film pulling assembly and a film taking assembly which are sequentially arranged along the unwinding feeding advancing direction;

the membrane cutting assembly can cut the membrane stretched by the membrane stretching assembly; the membrane taking assembly comprises a membrane suction plate and a membrane covering moving module; after the membrane unreeled by the membrane unreeling component is pulled to be membrane by the membrane pulling component, the membrane suction plate can be driven by the membrane covering moving module to move to be positioned between the membrane pulling component and the membrane cutting component, the membrane stretched by the membrane pulling component is sucked and continuously adsorbed after being cut to be membrane, and then the membrane covering moving module drives the belt to carry out membrane covering transfer with the adsorbed membrane.

9. The NFC lamination production device of claim 8, wherein the membrane cutting assembly comprises a cutting knife and a pressing block; the film pressing block is driven by the film pressing driving piece to move close to and press the film belt which is unreeled, the cutting knife is arranged at the discharge end of the film pressing block, and the cutting knife is driven by the film pressing driving piece to be aligned with the discharge end of the film pressing block to roll the diaphragm out for transverse cutting.

10. The NFC laminating production equipment according to any one of claims 1 to 9, wherein a manual detection position is arranged between the RF test station and the laminating station, and a manual detection material taking assembly is correspondingly arranged; the manual detection material taking assembly comprises a detection material taking sucker and a detection material taking moving module which can drive the detection material taking sucker to move;

and/or a blanking station is arranged on one side of the film covering station, and a blanking assembly is correspondingly arranged on one side of the film covering station; the blanking assembly comprises a blanking sucker and a blanking moving module which can drive the blanking sucker to move;

and/or a hot-pressing rolling mechanism is arranged between the rubberizing station and the RF testing station, and comprises a hot-pressing roller.

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