CN214492057U - Ultrahigh frequency tag antenna printing composite die cutting all-in-one machine - Google Patents

Abstract

The utility model provides an ultrahigh frequency tag antenna printing composite die cutting integrated machine, which relates to a chip binding positioning point and a chip binding point on an antenna body of an ultrahigh frequency tag antenna; antenna body's antenna layer one side still pastes second substrate layer or first substrate layer and second substrate layer, its characterized in that: the ultrahigh frequency label antenna printing and composite die cutting integrated machine comprises a printing mechanism, a first die cutting mechanism, a second die cutting mechanism and a tension swing roller control mechanism, wherein the printing mechanism is used for coating an adhesive on one side of an antenna layer to be processed or one side of a first substrate layer which is not adhered with the antenna layer according to the shape of an antenna body. The problem of how to avoid using etching process to produce the chip binding point and the chip binding setpoint of ultrahigh frequency electronic tags antenna among the prior art makes antenna layer or the antenna layer of compound first substrate layer move at the uniform velocity more and steadily in the course of working simultaneously is solved.

Description

Ultrahigh frequency tag antenna printing composite die cutting all-in-one machine

Technical Field

The utility model relates to an electronic tags technical field especially relates to a compound cross cutting all-in-one of hyperfrequency label antenna printing.

Background

At present, the chip binding point and the chip binding positioning point of the ultrahigh frequency tag antenna are still produced by adopting an etching process, and the etching process needs chemical substances such as hydrochloric acid and the like, so that the environment is greatly influenced, and therefore, how to avoid the chip binding point and the chip binding positioning point of the ultrahigh frequency tag antenna produced by the etching process and simultaneously enable the antenna layer or the antenna layer of the composite first base material layer to move more uniformly and stably in the processing process becomes a problem to be solved urgently.

In addition, how to completely avoid the problem of applying an etching process in the production process of the ultrahigh frequency tag antenna, how to prevent the antenna layer from shifting or shifting during transmission in the processing process, how to help the antenna layer to better shift or transmit while maintaining tension, how to help the antenna hole, the chip binding point and the chip binding point to perform accurate processing, how to improve the adhesive coating accuracy and avoid completely coating an adhesive on the antenna layer or the first substrate layer, how to further accurately determine the chip mounting position besides utilizing the chip binding point, and the problems become urgent to be solved.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a compound cross cutting all-in-one of hyperfrequency label antenna printing mainly solves the problem that above-mentioned prior art exists one: the problem of how to avoid the problem that the chip binding point and the chip binding point of the ultrahigh frequency tag antenna are produced by using an etching process and the antenna layer or the antenna layer compounded with the first substrate layer moves more uniformly and stably in the processing process is solved; the second problem is that: the problem of how to improve the coating precision of the adhesive is solved, and the adhesive is prevented from being completely coated on the antenna layer or the first substrate layer; the third problem is that: the problem of how to help the antenna hole, the chip binding point and the chip binding point to carry out accurate processing; the fourth problem is that: how to further accurately determine the chip mounting position in addition to utilizing the chip binding point; the fifth problem is that: the problem of how to completely avoid the application of an etching process in the production process of the ultrahigh frequency tag antenna; problem six: the problem of position deviation when the antenna layer moves or is transmitted is solved in the processing process; the ultrahigh frequency label antenna printing composite die-cutting integrated machine is provided.

In order to realize the purpose, the utility model discloses the technical scheme who adopts is: a printing and composite die-cutting integrated machine for an ultrahigh frequency tag antenna relates to the technical field that a chip binding positioning point formed by a die-cutting mode and a chip binding point formed by the die-cutting mode are arranged on an antenna body of the ultrahigh frequency tag antenna; antenna body's antenna layer one side still pastes second substrate layer or first substrate layer and second substrate layer, its characterized in that: the ultrahigh frequency tag antenna printing and composite die cutting integrated machine comprises a printing mechanism, a first die cutting mechanism, a second die cutting mechanism and a tension swing roller control mechanism, wherein the printing mechanism is used for coating an adhesive on one side of an antenna layer to be processed or one side of a first substrate layer which is not adhered with the antenna layer according to the shape of an antenna body, the first die cutting mechanism is used for die cutting a chip binding positioning point and a chip binding point of an ultrahigh frequency tag antenna, the second die cutting mechanism is used for die cutting the peripheral edge of the ultrahigh frequency tag antenna, and the tension swing roller control mechanism is used for controlling the tension swing roller.

Further, the ultrahigh frequency tag antenna printing composite die-cutting all-in-one machine further comprises a first unreeling mechanism for unreeling an antenna layer to be processed or a composite first substrate layer to be processed, a drying mechanism for drying the antenna layer coated with the adhesive according to the shape of the antenna body or a drying mechanism for drying the antenna layer coated with the adhesive according to the shape of the antenna body and the composite first substrate layer, an antenna hole processing mechanism for die-cutting the antenna hole of the ultrahigh frequency tag antenna, a composite mechanism for compounding the second substrate layer and the antenna layer or compounding the second substrate layer and the first substrate layer coated with the antenna layer, a first deviation correcting device, a second deviation correcting device, a third deviation correcting device, a second unreeling mechanism for unreeling the second substrate layer, a finished product reeling the processed antenna layer and the second substrate layer together or reeling the processed antenna layer and the first substrate layer and the second substrate layer together The coil mechanism, be used for carrying out the drive mechanism and the exhaust mechanism that pull to the antenna layer of antenna body and/or the antenna layer of compound first substrate layer and second substrate layer in the course of working of first die cutting mechanism and second die cutting mechanism.

Further, the printing mechanism comprises a second printing seat and a third printing seat, wherein the second printing seat is used for printing the first positioning mark and the mark block by adopting ink on one side of the antenna layer to be processed or on one side of the first base material layer which is not adhered with the antenna layer, and the third printing seat is used for coating the adhesive on one side of the antenna layer to be processed or on one side of the first base material layer which is not adhered with the antenna layer according to the shape of the antenna body.

Further, the tension swing roller control mechanism comprises a first tension swing roller control mechanism; the traction mechanism comprises a first traction device and a second traction device; the waste discharge mechanism comprises a first waste discharge winding mechanism and a second waste discharge winding mechanism;

the output port of the first unwinding mechanism corresponds to the input port of the first deviation correcting device, the output port of the first deviation correcting device corresponds to the input port of the second printing seat, the output port of the second printing seat corresponds to the input port of the third printing seat, the output port of the third printing seat corresponds to the input port of the drying mechanism, the output port of the drying mechanism corresponds to the input port of the second deviation correcting device, the output port of the second deviation correcting device corresponds to the input port of the first traction device, the output port of the first traction device corresponds to the input port of the antenna hole machining mechanism, the output port of the antenna hole machining mechanism corresponds to the input port of the composite mechanism, the output port of the second unwinding mechanism corresponds to the input port of the third deviation correcting device, the output port of the third deviation correcting device corresponds to the input port of the composite mechanism, the output port of the composite mechanism corresponds to the input port of the first die cutting mechanism, the output port of the first die cutting mechanism corresponds to the input port of the second die cutting mechanism and the input port of the first waste discharging mechanism, the output port of the second die cutting mechanism corresponds to the input port of the second waste discharging and winding mechanism and the input port of the second traction device, and the output port of the second traction device corresponds to the input port of the finished product winding mechanism;

or the output port of the first unreeling mechanism corresponds to the input port of the first deviation correcting device, the output port of the first deviation correcting device corresponds to the input port of the second printing seat, the output port of the second printing seat corresponds to the input port of the third printing seat, the output port of the third printing seat corresponds to the input port of the drying mechanism, the output port of the drying mechanism corresponds to the input port of the second deviation correcting device, the output port of the second deviation correcting device corresponds to the input port of the first traction device, the output port of the first traction device corresponds to the input port of the antenna hole machining mechanism, the output port of the antenna hole machining mechanism corresponds to the input port of the compounding mechanism, the output port of the second unreeling mechanism corresponds to the input port of the third deviation correcting device, the output port of the third deviation correcting device corresponds to the input port of the compounding mechanism, the output port of the compounding mechanism corresponds to the input port of the second die cutting mechanism, the output port of the second die cutting mechanism corresponds to the input port of the first die cutting mechanism and the second waste discharging and reeling mechanism, the output port of the first die-cutting mechanism corresponds to the input port of the first waste discharging winding mechanism and the input port of the second traction device, and the output port of the second traction device corresponds to the input port of the finished product winding mechanism.

Further, the traction mechanism further comprises a third traction device;

at the moment, the output port of the compound mechanism corresponds to the input port of the first die-cutting mechanism, the output port of the first die-cutting mechanism corresponds to the input port of the third traction device and the input port of the first waste discharge winding mechanism, the output port of the third traction device corresponds to the input port of the second die-cutting mechanism, and the output port of the second die-cutting mechanism corresponds to the input port of the second waste discharge winding mechanism and the input port of the second traction device;

or the output port of the compound mechanism corresponds to the input port of the second die-cutting mechanism, the output port of the second die-cutting mechanism corresponds to the input port of the third traction device and the input port of the second waste discharge winding mechanism, the output port of the third traction device corresponds to the input port of the first die-cutting mechanism, and the output port of the first die-cutting mechanism corresponds to the input port of the first waste discharge winding mechanism and the input port of the second traction device.

Further, the tension swing roller control mechanism also comprises a second tension swing roller control mechanism; the ultrahigh frequency label antenna printing composite die-cutting integrated machine further comprises a third unwinding mechanism used for unwinding the isolation layer on the antenna layer or the second substrate layer;

at the moment, an input port of the drying mechanism corresponds to an input port of a second tension swing roller control mechanism, and an output port of the second tension swing roller control mechanism corresponds to an input port of a second deviation correction device; and the output port of the third unwinding mechanism corresponds to the input port of the finished product winding mechanism.

Further, the antenna hole processing mechanism is a flat-pressing die-cutting machine for flat-pressing die-cutting antenna holes or a circular knife die-cutting machine for circular knife die-cutting antenna holes.

Further, the waste discharge mechanism is a second waste discharge winding mechanism; the traction mechanism further comprises a fourth traction device; the printing mechanism further comprises a fourth printing seat;

at the moment, the output port of the compound mechanism corresponds to the input port of the first die-cutting mechanism, the output port of the first die-cutting mechanism corresponds to the input port of the third traction device, the output port of the third traction device corresponds to the input port of the fourth printing seat, the output port of the fourth printing seat corresponds to the input port of the fourth traction device, the output port of the fourth traction device corresponds to the input port of the second die-cutting mechanism, and the output port of the second die-cutting mechanism corresponds to the input port of the second waste discharge winding mechanism and the input port of the second traction device;

or the output port of the compound mechanism corresponds to the input port of the second die-cutting mechanism, the output port of the second die-cutting mechanism corresponds to the input port of the third traction device, the output port of the third traction device corresponds to the input port of the fourth printing seat, the output port of the fourth printing seat corresponds to the input port of the fourth traction device, the output port of the fourth traction device corresponds to the input port of the first die-cutting mechanism, and the output port of the first die-cutting mechanism corresponds to the input port of the second waste discharge winding mechanism and the input port of the second traction device.

Further, the waste discharge mechanism is a first waste discharge winding mechanism; the traction mechanism further comprises a fourth traction device; the printing mechanism further comprises a fourth printing seat;

at the moment, the output port of the compound mechanism corresponds to the input port of the first die-cutting mechanism, the output port of the first die-cutting mechanism corresponds to the input port of the third traction device, the output port of the third traction device corresponds to the input port of the fourth printing seat, the output port of the fourth printing seat corresponds to the input port of the fourth traction device, the output port of the fourth traction device corresponds to the input port of the second die-cutting mechanism, and the output port of the second die-cutting mechanism corresponds to the input port of the first waste discharge winding mechanism and the input port of the second traction device;

or the output port of the compound mechanism corresponds to the input port of the second die-cutting mechanism, the output port of the second die-cutting mechanism corresponds to the input port of the third traction device, the output port of the third traction device corresponds to the input port of the fourth printing seat, the output port of the fourth printing seat corresponds to the input port of the fourth traction device, the output port of the fourth traction device corresponds to the input port of the first die-cutting mechanism, and the output port of the first die-cutting mechanism corresponds to the input port of the first waste discharging winding mechanism and the input port of the second traction device.

Further, the first die cutting mechanism is composed of a flat-press die cutting mechanism, and the flat-press die cutting mechanism is a flat-press die cutting machine comprising at least one die cutting tool for flat-press die cutting of chip binding positioning points and chip binding points;

or the first die-cutting mechanism consists of a circular knife die-cutting mechanism, and the circular knife die-cutting mechanism is a circular knife die-cutting machine comprising at least one rolling cutter for die-cutting a chip binding positioning point and a chip binding point by a circular knife;

or the first die cutting mechanism is a mixed die cutting mechanism formed by mixing a flat-pressing die cutting mechanism and a circular cutter die cutting mechanism, and the mixed die cutting mechanism is a mixed die cutting machine comprising at least one die cutting tool for flat-pressing die cutting chip binding positioning points or chip binding positioning points and at least one hob tool for circular cutter die cutting chip binding points or chip binding positioning points;

the second die-cutting mechanism is a flat-pressing die-cutting machine for flat-pressing the peripheral edge of the die-cutting antenna body or a circular knife die-cutting machine for circular knife die-cutting the peripheral edge of the antenna body;

the first die cutting mechanism is divided into a flat die cutting machine for carrying out flat die cutting on one chip binding point or a circular knife die cutting machine for carrying out circular knife die cutting, and a flat die cutting machine for carrying out flat die cutting on the other chip binding point and the chip binding point or a circular knife die cutting machine for carrying out circular knife die cutting;

an exposure device is additionally arranged between the second printing seat and the third printing seat; and/or an exposure device is arranged behind the fourth printing seat.

In view of the above technical features, the utility model discloses following beneficial effect has:

1. in the ultrahigh frequency tag antenna printing composite die-cutting integrated machine, before or at the front and back of the drying mechanism, the tension swing roller control mechanism (namely the first tension swing roller control mechanism and the second tension swing roller control mechanism) is arranged to indirectly control the tension of the antenna layer or the antenna layer compounded with the first substrate layer in the moving process, so as to ensure that the antenna layer or the antenna layer compounded with the first substrate layer can move stably at a constant speed, and is stressed uniformly in the moving process to avoid wrinkles and further influence the processing effect, and the tension swing roller control mechanism helps the antenna layer coated with glue or the antenna layer compounded with the first substrate layer to enter the drying mechanism more stably at a constant speed, and to enter the drying mechanism 3 smoothly at a flat laying, constant speed, drying glue, preventing accidental adhesion, and promoting glue stoving effect and/or drying efficiency. And the tension on the antenna layer can be adjusted to stretch the antenna layer and prevent the antenna layer from slipping.

2. The utility model provides an ultrahigh frequency label antenna adopts and binds the setpoint to chip binding point, chip and carry out the fashioned mode of cross cutting, for example concora crush cross cutting and/or circular knife cross cutting, can make the ultrahigh frequency label antenna of full cross cutting break away from etching process, can effectively reduce influence and/or pollution that the chemical substance that produces because of etching process causes the environment.

3. The utility model provides an ultrahigh frequency label antenna punches also can adopt the cross cutting mode to the antenna hole, for example concora crush cross cutting and/or circular knife cross cutting, can make the ultrahigh frequency label antenna of full cross cutting break away from etching process, can effectively reduce influence and/or pollution that the chemical material that produces because of etching process causes the environment. Even without any etching process, the ultrahigh frequency tag antenna can be produced to the lowest point of environmental pollution, even basically harmless.

4. The utility model provides a hyperfrequency label antenna also can adopt the cross cutting mode to the border position all around of antenna body, for example concora crush cross cutting and/or circular knife cross cutting, can make the hyperfrequency label antenna of full cross cutting break away from etching process, can effectively reduce influence and/or pollution that the chemical material that produces because of etching process causes the environment. The ultrahigh frequency tag antenna can be produced to the lowest point of environmental pollution without any etching process, and is even basically harmless.

5. The utility model discloses in a compound cross cutting all-in-one of hyperfrequency label antenna printing, to chip binding point, chip binding setpoint and antenna body border position's processing equipment position and processing order all around can the interchange, do not influence chip binding point, chip binding setpoint and antenna body border position's processing effect all around.

6. The traction mechanism can be composed of at least two traction devices, for example, two traction devices place a die cutting mechanism (including an antenna hole processing mechanism, a composite mechanism, a first die cutting mechanism, a second die cutting mechanism and the like) between the two traction devices, the two traction devices help the die cutting mechanism to perform die cutting in-process antenna layer or antenna layer of a composite first substrate layer and second substrate layer to well move or transmit effect, the moving force is enhanced, the shell is not easy to clamp in the moving process, meanwhile, the antenna layer of the die cutting mechanism in-process antenna layer or composite first substrate layer or antenna layer of the composite first substrate layer and second substrate layer is straightened or flattened through the two traction devices, good tension is kept, the die cutting mechanism can be convenient to process, and the die cutting processing effect is improved. During the manufacturing process, the traction mechanism can effectively help the antenna layer to maintain tension and better move or drive.

7. The second deviation correcting device can help to correct the moving position of the antenna layer which is output from the drying mechanism and coated with the adhesive or the antenna layer of the composite first base material layer, accurately positions and corrects the moving direction, ensures that the transmission position of the antenna layer which enters a subsequent processing procedure or the antenna layer of the composite first base material layer is accurate, and helps to promote the die cutting effect and the die cutting accuracy of the subsequent die cutting mechanism. In the course of working, the second deviation correcting device can prevent effectively that the position from taking place the skew when antenna layer removes or the transmission.

8. The second winding mechanism that wastes discharge can promote the effect of wasting discharge, promotes product processingquality.

9. The antenna hole, the chip binding point and the chip binding positioning point of the ultrahigh frequency tag antenna are all subjected to die cutting by utilizing the antenna hole processing mechanism, the first die cutting mechanism and the second die cutting mechanism, so that the use of an etching process is effectively avoided, the pollution caused by the etching process to the environment is reduced or even completely avoided, meanwhile, when the adhesive is coated, a printing seat design (such as a third printing seat) is adopted, the adhesive is precisely coated according to the shape of the antenna layer body (instead of coating the adhesive completely, the adhesive is effectively prevented from being coated on the antenna layer or the first substrate layer completely), namely, the adhesive is printed or coated only in the place where the antenna layer body is formed by final die cutting, no adhesive exists between other produced antenna layer waste materials and second substrate layer waste materials, or no adhesive exists between the first substrate layer waste material and the second substrate layer waste material compounded on one side of the antenna layer, therefore, the quality of the final finished product of the ultrahigh frequency tag antenna is not influenced, the using amount of the adhesive can be effectively saved, and the production cost is saved.

10. The printing mechanism for accurately coating the adhesive and simultaneously printing the first positioning mark is composed of a third printing seat, the third printing seat has the function of accurately coating the adhesive according to the shape of the antenna layer body (at the moment, the adhesive with color is adopted for accurate coating, preferably, the adhesive is coated according to the shape of the antenna layer body and slightly larger than the shape of the antenna layer body), and meanwhile, the printing mechanism also has the function of printing the first positioning mark by using ink (preferably UV ink), and can realize two functions at one time. Therefore, the production efficiency is higher, and the production steps can be adjusted according to the requirements of customers, and the exposure device is not needed.

11. The printing mechanism for accurately coating the adhesive and printing the first positioning mark can also alternatively consist of a second printing seat and a third printing seat, wherein the second printing seat is arranged on one side of the antenna layer or one side of the first base material layer compounded on the antenna layer, which is not adhered with the antenna layer, and the first positioning mark and the marking blocks (also can be a plurality of marking blocks) are printed by using ink (preferably UV ink), the shapes of the marking blocks are the same as the shape of the antenna layer body, and then the third printing seat prints or coats the adhesive on each marking block, so that the method of improving the coating accuracy of the adhesive and avoiding coating the adhesive on the antenna layer or on the first base material layer is realized, the use amount of the adhesive is effectively saved, and the production cost is saved.

12. The first positioning mark is in the subsequent die cutting processes of utilizing the antenna hole processing mechanism, the first die cutting mechanism and the second die cutting mechanism to produce the antenna hole of the ultrahigh frequency tag antenna, the chip binding point and the chip binding point, and the like, and plays a role in positioning, the antenna hole processing mechanism convenient to use, the first die cutting mechanism and the second die cutting mechanism utilize the first positioning mark, accurate antenna hole is carried out on an antenna layer, die cutting processing of the chip binding point and the chip binding point is carried out, the product processing precision is improved, and the product quality is improved.

13. The setting of first deviation correcting device can help to prepare the transportation position that gets into the antenna layer of printing mechanism or the antenna layer of compound first substrate layer and carry out the position and correct, guarantees that it gets into printing mechanism according to the assigned position, can guarantee like this that printing mechanism (second printing seat and third printing seat promptly) prints first locating mark accurately, prints or coats the adhesive according to antenna layer body shape, guarantees the precision of printing mechanism processing.

Drawings

Fig. 1 is a schematic structural diagram of an uhf tag antenna in embodiment 1.

Fig. 2 is a schematic cross-sectional view of the uhf tag antenna (without the first substrate layer) in example 1.

Fig. 3 is a schematic cross-sectional view of an uhf tag antenna (including a first substrate layer) in example 1.

Fig. 4 is a schematic structural diagram of an uhf tag antenna and a first positioning mark in embodiment 1;

FIG. 5 is a schematic structural diagram of an integrated UHF tag antenna printing, composite die-cutting machine in example 1;

FIG. 6 is a schematic structural diagram of an integrated UHF tag antenna printing, composite die-cutting machine in example 2;

FIG. 7 is a schematic structural diagram of an integrated UHF tag antenna printing, composite die-cutting machine in example 3;

FIG. 8 is a schematic structural diagram of an integrated UHF tag antenna printing, composite die-cutting machine in example 4;

FIG. 9 is a schematic structural diagram of an integrated UHF tag antenna printing, composite die-cutting machine in example 5;

fig. 10 is a schematic structural diagram of an ultrahigh frequency label antenna printing composite die-cutting all-in-one machine in embodiment 6.

In the figure: 1 is a first unwinding mechanism; 3 is a drying mechanism; 4, an antenna hole processing mechanism; 6 is a composite mechanism; 7, a second unwinding mechanism; 10 is a second die-cutting mechanism; 11 is a first waste discharge winding mechanism; 12 is a third unwinding mechanism; 13 is a finished product winding mechanism; 14, binding a positioning point for the chip; 15 is a chip binding point; 16 is an antenna hole; 17 is an antenna body; 18 is an aluminum foil; 19 is adhesive printed or coated on the third printing base; 20 is paper as a second base material layer, and 21 is a PET layer as a first base material layer; 22 is an adhesive for pre-compounding the PET layer and the aluminum foil; 23 is a first traction device; 24 is a second traction device; 25 is a second deviation correcting device; 26 is a second waste discharge winding mechanism; 27 is a first die-cutting mechanism; 29 is a second printing seat; 30 is a third printing seat; 31 is a fourth printing seat; 34 is a first deviation rectifying device; 36 is a first positioning identifier; 38 is a sticking block; 39 is a third deviation rectifying device; 40 is a first tension swing roller control mechanism; 41 is a third traction device; 42 is a second tension swing roller control mechanism; and 43 is a fourth traction device.

Detailed Description

The present invention will be further described with reference to the following detailed description. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Furthermore, it should be understood that various changes and modifications of the present invention may be made by those skilled in the art after reading the teachings of the present invention, and these equivalents also fall within the scope of the appended claims.

Referring to fig. 1 to 5, in embodiment 1, this embodiment 1 provides an ultrahigh frequency tag antenna printing composite die-cutting integrated machine, and relates to that a chip binding positioning point 14 formed by a die-cutting manner and a chip binding point 15 formed by a die-cutting manner are arranged on an antenna body 17 of an ultrahigh frequency tag antenna; antenna body 17's antenna layer one side still pastes second substrate layer or first substrate layer and second substrate layer, the compound cross cutting all-in-one of hyperfrequency label antenna printing includes:

the first unwinding mechanism 1 is used for unwinding the antenna layer to be processed or the antenna layer to be processed of the composite first substrate layer; in this embodiment 1, the first deviation rectification device 34 is disposed near the first unwinding mechanism 1, and is configured to rectify a deviation of an antenna layer to be processed or an antenna layer of a composite first substrate layer unwound by the first unwinding mechanism 1, that is, perform reference positioning, correct and/or calibrate a transfer direction thereof, so that the subsequent second printing base 29 can more accurately print the first positioning identifier 36 on the antenna layer or the antenna layer of the composite first substrate layer;

a second printing seat 29 for printing the first positioning mark 36 and/or the mark block by using ink on one side of the antenna layer to be processed or on one side of the first substrate layer not adhered with the antenna layer, in this embodiment 1, it is preferable that the first unwinding mechanism 1 unwinds the material to be processed after the first substrate layer and the antenna layer are adhered, at this time, one side of the first substrate layer not adhered with the antenna layer is a front side, one side of the first substrate layer adhered with the antenna layer is a back side, and the actual back side is used for coating an adhesive on the antenna layer to be processed;

the front side is used for printing the first positioning mark 36 and/or the mark block by the second printing seat 29 by adopting ink, the first positioning mark 36 is printed to provide positioning for the subsequent adhesive coating process of the third printing seat 30, the antenna hole processing process, the process of compounding with the second substrate layer, the first die cutting process and the second die cutting process, the respective processing precision of the antenna hole processing mechanism 4, the first die cutting mechanism 27 and the second die cutting mechanism 10 can be effectively improved, the hot drum compounding is carried out after the second substrate layer is accurately sleeved with the antenna layer, and the adhesive is accurately coated on the third printing seat 30; the ink may be a quick-drying ink or may be accelerated by the addition of an exposure device (e.g., ultraviolet, UV) and/or a dryer.

The third printing seat 30 is used for correspondingly coating an adhesive on the antenna layer to be processed according to the specification and the size of the antenna in the finished ultrahigh frequency label, the shape formed by the adhesive is similar to the actual shape (namely the full pattern of the antenna) of the antenna in the ultrahigh frequency label, but the shape formed by the adhesive is slightly larger than the shape of the antenna in the finished ultrahigh frequency label, so that the quality of the finished ultrahigh frequency label is prevented from being influenced by errors of subsequent processing procedures, the antenna layer of the finished ultrahigh frequency label is ensured to be uniformly bonded with the second substrate layer, and particularly the edge parts of the antenna layer and the second substrate layer can be bonded.

A printing mechanism for coating an adhesive on one side of the antenna layer to be processed or one side of the first substrate layer, to which the antenna layer is not attached, according to the shape of the antenna body, that is, a third printing seat 30 for coating an adhesive on one side of the antenna layer to be processed or one side of the first substrate layer, to which the antenna layer is not attached, according to the shape of the antenna body, according to the mark block;

the first tension swing roller control mechanism 40 is used for controlling the operation of the first tension swing roller, indirectly controlling the tension of the antenna layer or the antenna layer compounded with the first base material layer in the moving process, ensuring that the antenna layer or the antenna layer compounded with the first base material layer can move at a constant speed and stably, and is stressed uniformly in the moving process, so that the phenomenon that the machining effect is influenced by wrinkles is avoided; in this embodiment 1, first tension pendulum roller control mechanism 40 is located and is third printing seat 30 and stoving mechanism 3 between, also is antenna layer behind the help coating glue or the antenna layer coating glue of compound first substrate layer, can tile, at the uniform velocity, steadily get into stoving mechanism 3, dries glue, prevents unexpected adhesion, and promotes glue stoving effect and/or drying efficiency. And the tension on the antenna layer can be adjusted to stretch the antenna layer and prevent the antenna layer from slipping.

The drying mechanism 3 is used for drying the antenna layer coated with the adhesive according to the shape of the antenna body or the drying mechanism 3 is used for drying the antenna layer of the composite first base material layer coated with the adhesive according to the shape of the antenna body;

the second deviation correcting device 25 is arranged between the drying mechanism 3 and the antenna hole processing mechanism 4, in this embodiment 1, the second deviation correcting device 25 is arranged on the dried antenna layer or the dried antenna layer of the composite first substrate layer to correct the deviation, that is, to perform reference positioning, correct and/or calibrate the transfer direction, so that the subsequent first traction device 23 is further pulled to the antenna hole processing mechanism 4 for processing;

the traction mechanism is used for drawing the antenna layer of the antenna body 17 and/or the antenna layer compounded with the first base material layer and the second base material layer in the processing process of the antenna hole processing mechanism, the first die-cutting mechanism and the second die-cutting mechanism 10; the traction mechanism is a first traction device 23 and a second traction device 24; the first traction device 23 is located in front of the antenna hole machining mechanism 4, and the second traction device 24 is located between the second die-cutting mechanism 10 and the finished product winding mechanism 13. In the help antenna hole processing agency course of working through two draw gear, the good removal or the transmission effect of the antenna layer of the cross cutting in-process antenna layer or compound first substrate layer of first die cutting mechanism and second die cutting mechanism or the antenna layer of compound first substrate layer and second substrate layer, reinforcing removal dynamics, be difficult to card the shell at the removal in-process, simultaneously through two draw gear with in the antenna hole course of working, the antenna layer of the cross cutting in-process antenna layer or compound first substrate layer of first die cutting mechanism and second die cutting mechanism or the antenna layer of compound first substrate layer and second substrate layer straightens or draws level, keep its good tension, can be convenient for die cutting mechanism to process, improve the effect of cross cutting processing. During the manufacturing process, the traction mechanism can effectively help the antenna layer to maintain tension and better move or drive.

The antenna hole machining mechanism 4 is used for machining (for example, punching) an antenna hole 16 of the ultrahigh frequency tag antenna, and after the antenna hole is machined, the waste is directly recovered in the process, for example, the antenna hole machining waste directly falls down and is recovered by an antenna hole waste collecting device (not shown in the drawing);

a second unwinding mechanism 7 for unwinding a second substrate layer;

in this embodiment 1, the first deviation rectification device 34 is disposed near the second unwinding mechanism 7, and is configured to rectify a deviation of the antenna layer of the second substrate layer unwound by the second unwinding mechanism 7, that is, perform reference positioning, correct and/or calibrate a transfer direction thereof, so that the subsequent composite mechanism 6 can more accurately compound the second substrate layer and the antenna layer or compound the second substrate layer and the first substrate layer to which the antenna layer is attached, for example, by hot drum compounding;

a composite mechanism 6 for compositing the second substrate layer with the antenna layer or compositing the second substrate layer with the first substrate layer adhered with the antenna layer;

a first die-cutting mechanism 27 for die-cutting the chip binding site 14 and the chip binding site 15 of the ultra-high frequency tag antenna;

a first waste discharge winding mechanism 11 for winding the waste antenna processed by the first die-cutting mechanism 27 or winding the waste antenna processed by the first die-cutting mechanism 27 and the waste first base material layer;

a second die-cutting mechanism 10 for die-cutting the peripheral edge of the uhf tag antenna;

a second waste discharge winding mechanism 26 for winding the waste antenna processed by the second die-cutting mechanism 10;

a finished product winding mechanism 13 for winding the processed antenna layer and the second substrate layer together or winding the processed antenna layer, the first substrate layer and the second substrate layer together;

the output port of the first unreeling mechanism 1 corresponds to the input port of the first deviation correcting device 34, the output port of the first deviation correcting device 34 corresponds to the input port of the second printing seat 29, the output port of the second printing seat 29 corresponds to the input port of the third printing seat 30, the output port of the third printing seat 30 corresponds to the input port of the first tension swing roller control mechanism 40, the output port of the first tension swing roller control mechanism corresponds to the input port of the drying mechanism 3, the output port of the drying mechanism 3 corresponds to the input port of the second deviation correcting device 25, the output port of the second deviation correcting device 25 corresponds to the input port of the first traction device 23, the output port of the first traction device 23 corresponds to the input port of the antenna hole machining mechanism 4, the output port of the antenna hole machining mechanism 4 corresponds to the input port of the composite mechanism 6, meanwhile, the output port of the second unreeling mechanism 7 corresponds to the input port of the third deviation correcting device 39, and the output port of the third deviation correcting device 39 corresponds to the input port of the composite mechanism 6, the output port of the compound mechanism 6 corresponds to the input port of the first die-cutting mechanism 27, the output port of the first die-cutting mechanism 27 corresponds to the input port of the second die-cutting mechanism 10 and the input port of the first waste discharging winding mechanism 11, the output port of the second die-cutting mechanism 10 corresponds to the input port of the second waste discharging winding mechanism 26 and the input port of the second traction device 24, and the output port of the second traction device 24 corresponds to the input port of the finished product winding mechanism 13.

Alternative options are: the output port of the compound mechanism 6 corresponds to the input port of the second die-cutting mechanism 10, the output port of the second die-cutting mechanism 10 corresponds to the input port of the first die-cutting mechanism 27 and the second waste discharging and winding mechanism 26, the output port of the first die-cutting mechanism 27 corresponds to the input port of the first waste discharging and winding mechanism 11 and the input port of the second traction device 24, and the output port of the second traction device 24 corresponds to the input port of the finished product winding mechanism 13. Namely, the positions of the first die-cutting mechanism 27 and the second die-cutting mechanism 10 can be interchanged, the corresponding component connection modes are correspondingly adjusted, and the sequence of the working procedures of the first die-cutting mechanism 27 and the second die-cutting mechanism 10 is also interchanged, so that the production of products is not influenced, and the processing effect is the same.

The first die-cutting mechanism 27 is a flat-press die-cutting mechanism, and the flat-press die-cutting mechanism is a flat-press die-cutting machine comprising at least one die-cutting cutter for flat-press die-cutting the chip binding and positioning points 14 and 15;

or the first die-cutting mechanism 27 is composed of a circular knife die-cutting mechanism, and the circular knife die-cutting mechanism is a circular knife die-cutting machine comprising at least one rolling cutter for die-cutting the chip binding positioning points 14 and the chip binding points 15 by the circular knife;

or the first die cutting mechanism 27 is a mixed die cutting mechanism formed by mixing a flat-pressing die cutting mechanism and a circular cutter die cutting mechanism, and the mixed die cutting mechanism is a mixed die cutting machine comprising at least one die cutting cutter for flat-pressing die cutting chip binding and positioning points 14 or chip binding and positioning points 15 and at least one hob cutter for circular cutter die cutting chip binding and positioning points 15 or chip binding and positioning points 14.

The second die cutting mechanism 10 is a flat press die cutting machine for flat pressing the peripheral edge of the die cutting antenna body 17, or a circular knife die cutting machine for circular knife die cutting the peripheral edge of the die cutting antenna body 17.

That is to say, the first die cutting mechanism 27 and the second die cutting mechanism 10 can select the flat-pressing die cutting mechanism and/or the circular knife die cutting mechanism according to the actual requirement to realize the die cutting process, so as to meet the requirements of the full-die-cut ultrahigh frequency tag antenna on the die cutting process, in particular the requirements of the chip binding positioning points 14, the chip binding points 15 and the peripheral edges of the antenna body 17 on the die cutting process.

The chip binding points 15 are two, and the first die cutting mechanism 27 is divided into a flat die cutting machine for performing flat die cutting on one of the chip binding points 15 or a circular knife die cutting machine for performing circular knife die cutting, and a flat die cutting machine for performing flat die cutting on the other of the chip binding points 15 and the chip binding points 14 or a circular knife die cutting machine for performing circular knife die cutting.

The chip binding positioning points 14 and the chip binding points 15 of the ultrahigh frequency tag antenna are manufactured in a die cutting mode, so that the etching process can be avoided in the process of producing the chip binding positioning points 14 and the chip binding points 15, and the pollution of chemical substances to the environment can be effectively reduced; in addition, the chip binding positioning points 14 and the chip binding points 15 formed in the die cutting mode are smooth and smooth in the peripheral edges, uneven edge shapes cannot exist, and the quality of the ultrahigh frequency tag antenna is improved. The peripheral edge of the antenna body 17 is formed by die cutting. The antenna body 17 is further provided with an antenna hole 16 formed by die cutting. That is to say, each part on the ultrahigh frequency tag antenna can be carried out by adopting a die cutting mode, the whole ultrahigh frequency tag antenna can be produced by adopting the die cutting mode, the etching process is completely separated, the pollution to the environment is minimized, and even no chemical pollution is caused.

The die cutting mode can adopt flat pressing die cutting and/or circular knife die cutting, which is also called rolling cutting.

In this embodiment 1, there are two chip attachment points 15, one antenna hole 16, and a gap formed between the chip attachment points 15 communicates between the antenna hole 16 and the outside of the antenna.

A second substrate layer or a first substrate layer and a second substrate layer are further adhered to one side of the antenna layer of the antenna body 17, preferably, the first substrate layer is a mylar, preferably, a PET layer 21 of the first substrate layer, and the second substrate layer is a mylar or paper 20, wherein the mylar is preferably, a PET layer; the antenna of the antenna layer may be a metal foil, such as an aluminum foil, a copper foil, etc., and in this embodiment 1, the antenna of the antenna layer is preferably an aluminum foil 18.

Between the first traction device 23 and the second traction device 24, the antenna layer and/or the first substrate layer and/or the second substrate layer which are processed correspondingly to the aforementioned components can be moved or conveyed well, and meanwhile, the tension of the antenna layer and/or the first substrate layer and/or the second substrate layer can be kept stable and uniform in the moving process, especially the tension of the die cutting position is stable and uniform, so that the processing operation corresponding to the aforementioned components is facilitated, and the accuracy of the processing operation is ensured.

The vicinity of the bonding block 38 refers to that a first positioning mark 36 is arranged at a specified distance around the bonding block 38 or at two sides of the outermost edge or at two sides of the periphery of the bonding block 38, and in the processing process of the subsequent antenna hole processing mechanism 4, the first positioning mark 36 in this embodiment 1 is arranged at two sides of the outermost edge of the bonding block 38, referring to fig. 4, the first positioning mark 36 can provide a positioning basis for the antenna hole processing mechanism 4, the first module mechanism 27 and the second module mechanism 10, improve the accuracy of respective processing of the antenna hole processing mechanism 4, the first module mechanism 27 and the second module mechanism 10, and improve the product quality, for example, the outer contour of a specific tag antenna on an antenna layer is positioned by the first positioning mark 36, which is also called as cover mold positioning. The first positioning mark 36 may be printed with ink, preferably UV ink, and the adhesive applied to the adhesive block may be colored (ink or pigment powder, such as red or black, etc.).

The second printing seat 29 is used for printing the first positioning mark 36 and the mark block by adopting ink on one side of the antenna layer to be processed or one side of the first substrate layer which is not adhered with the antenna layer; the third printing seat 30 is used for coating an adhesive on one side of the antenna layer to be processed or one side of the first base material layer, which is not adhered with the antenna layer, according to the shape of the antenna body according to the mark blocks.

The first positioning mark 36 and the mark block are formed by printing the groove part of the second printing seat 29, the groove part of the second printing seat 29 is used for installing ink, preferably UV ink, the shape of the groove part is matched with the second positioning mark 36 and the shape of the antenna body, namely, the shape of each groove part is the shape of the second positioning mark 36 and the shape of the antenna body to be cut, the UV ink is printed according to the shape, a plurality of groove parts can be simultaneously arranged, the printing of the second positioning mark 36 and a plurality of mark blocks is simultaneously realized, the mark block and the paste block 38 are formed, namely, the paste block 38 is formed after the paste agent 19 is printed or coated on the mark block, and the adhesive is convenient and saved. The marker blocks are not shown in the drawings.

The groove portion of the third printing seat 30 is used for installing an adhesive, and the shape of the groove portion is matched with the shape of the antenna body, that is, the shape of each groove portion is the shape of the antenna body to be cut, so that the adhesive is printed in the shape, and a plurality of groove portions can be arranged at the same time, so that the printing of a plurality of bonding blocks 38 is realized, and the convenience and the adhesive saving are realized. In this embodiment 1, preferably, the shape of the groove portion is slightly larger than the shape of the antenna body, and is used to compensate various errors (for example, a composite error between the second substrate layer and the antenna layer, a processing error of the antenna hole, a die cutting error of the first die cutting process, and a die cutting error of the second die cutting process) generated in the subsequent antenna hole processing process and/or the composite process of the composite mechanism and/or the first die cutting process and/or the second die cutting process, and provide a certain space for the various errors (especially, an error generated by the integral movement of the shape position of the antenna body after being processed in the processing process and the original predetermined position thereof), and improve the qualification rate of product processing.

The mark block can be formed by peripheral lines matched with the shape of the antenna body, or the mark block is a color block area printed according to the shape of the antenna body, and the color block area has the same shape as the antenna body.

There is not first substrate layer in the ultrahigh frequency label antenna course of working, directly adopt antenna layer to add man-hour first printing seat 28 or third printing seat 30 at one side coating adhesive 19 on antenna layer, bind setpoint 14 and chip binding point 15 to the chip when first die cutting mechanism and carry out the cross cutting, second die cutting mechanism 10 carries out the cross cutting to the edge all around of antenna body 17, antenna hole processing mechanism 4 all only carries out the cross cutting to antenna layer when carrying out the cross cutting to antenna hole 16, but does not carry out the cross cutting to the second substrate layer. The adhesive 19 printed or coated on the first printing base 28 or the third printing base 30 is used to combine the antenna layer and the second substrate layer by the combining mechanism 7, that is, the antenna layer and the second substrate layer are bonded together by the adhesive 19. The finished product of the ultrahigh frequency tag antenna produced under the condition is that an antenna layer (namely, an aluminum foil 18) and the antenna layer are adhered to a second substrate layer (namely, paper 20) through an adhesive 19 printed or coated on a first printing seat 28 or a third printing seat 30 from top to bottom in sequence, as shown in fig. 2.

When the ultrahigh frequency label antenna is processed, the first base material layer can be optionally added, or the first base material layer can be omitted. Preferably adopt first substrate layer, first substrate layer is used for supporting the antenna on the antenna layer, in antenna layer course of working, first substrate layer carries out guard action to the antenna, first printing seat 28 or third printing seat 30 do not paste the one side coating adhesive on antenna layer at first substrate layer this moment, bind setpoint 14 and chip binding point 15 to the chip and carry out the cross cutting when first die-cutting mechanism, second die-cutting mechanism 10 carries out the cross cutting to the edge all around of antenna body 17, all can carry out the cross cutting simultaneously with first substrate layer and antenna layer when antenna hole processing agency 4 carries out the cross cutting to antenna hole 16, but do not carry out the cross cutting to the second substrate layer. The adhesive 19 printed or coated by the first printing base 28 or the third printing base 30 is used for laminating the first substrate layer and the second substrate layer together through the laminating mechanism 6, that is, the first substrate layer and the second substrate layer are bonded together by the adhesive 19. The finished ultrahigh frequency tag antenna product produced under the condition is characterized in that an antenna layer (namely, an aluminum foil 18) and an antenna layer pasting composite first substrate layer (namely, a PET layer 21, here pasting composite means that the PET layer 21 pre-compounds the PET layer 21 and the aluminum foil 18 through a bonding agent 22 for pre-compounding and pasting the PET layer 21 and the aluminum foil 18, then the antenna layer of the composite first substrate layer is placed and rolled into a first printing seat 28 or a second printing seat 29 and a third printing seat 30 through a first unwinding mechanism 1), the first substrate layer (namely, the PET layer 21) is pasted and compounded with a second substrate layer (namely, paper 20) through a bonding agent 19 printed or coated by the first printing seat 28 or the third printing seat 30, and details are shown in fig. 3.

The second deviation correcting device 25 is used for correcting the position and calibrating the position of the antenna layer or the antenna layer of the composite first base material layer coming out of the drying mechanism 3 when the antenna layer or the antenna layer of the composite first base material layer moves forwards (namely, in the transportation process or the moving process), especially, when a side position error or a side position deviation occurs in the antenna layer or the antenna layer of the composite first base material layer, the second deviation correcting device 25 plays a role in correcting, namely, the second deviation correcting device 25 performs reference positioning on the antenna layer or the antenna layer of the composite first base material layer coming out of the drying mechanism 3, corrects the moving direction of the antenna layer or the antenna layer of the composite first base material layer, ensures that the advancing direction and the positions of two sides are accurate when the antenna layer or the antenna layer of the composite first base material layer enter the first traction device 23, and helps to promote and/or ensure the processing accuracy of the subsequent first die-cutting mechanism and/or the second die-cutting mechanism. Or if the antenna layer or the antenna layer of the composite first substrate layer shifts in the antenna moving and transmitting position of the dried antenna layer or the antenna of the composite first substrate layer caused by thermal expansion in the drying mechanism, the second deviation correcting device 25 can also perform the functions of position correction and position calibration. Similarly, the first deviation correcting device 34 performs position correction and position calibration on the antenna layer to be processed output by the first unwinding mechanism 1 or the antenna layer to be processed of the composite first substrate layer; the third deviation correcting device 39 performs position correction and position calibration on the second substrate layer output by the second unwinding mechanism 7.

Referring to fig. 6, embodiment 2, the difference between this embodiment 2 and embodiment 1 is: in the embodiment 2, a third drawing device 41 is additionally arranged, and the third drawing device 41 is located between the first die-cutting mechanism 27 and the second die-cutting mechanism 10, namely, the output port of the first die-cutting mechanism 27 corresponds to the input port of the first waste winding mechanism 11 and the input port of the third drawing device 41, and the input port of the third drawing device 41 corresponds to the input port of the second die-cutting mechanism 10. This design is through increasing third draw gear 41, can further help keeping antenna layer and/or first substrate layer and/or second substrate layer at the removal in-process tension steady, even, especially needs the tension at cross cutting position more stable and more even, and the cross cutting processing operation of being convenient for guarantees the accuracy of cross cutting processing operation.

The antenna hole processing mechanism 4 is used for processing the antenna hole 16 of the ultrahigh frequency tag antenna in a punching mode.

Referring to fig. 7, an embodiment 3, this embodiment 3 is different from embodiment 2 in that: in this embodiment 3, a second tension swing roller control mechanism 42 is newly added, and the second tension swing roller control mechanism 42 is located between the drying mechanism 3 and the second deviation rectifying device 25, that is, an output port of the drying mechanism 3 corresponds to an input port of the second tension swing roller control mechanism 42, and an output port of the second tension swing roller control mechanism 42 corresponds to an input port of the second deviation rectifying device 25. The second tension swing roller control mechanism 42 is used for controlling the second tension swing roller to operate, indirectly controlling the tension of the antenna layer or the antenna layer composited with the first substrate layer (especially the antenna layer dried by the drying mechanism 3 or the antenna layer composited with the first substrate layer) in the moving process, ensuring that the antenna layer or the antenna layer composited with the first substrate layer can move stably at a constant speed, and is stressed uniformly in the moving process, and avoiding the occurrence of wrinkles to further influence the processing effect; the antenna layer after can help drying mechanism 3 stoving or the antenna layer of compound first substrate layer tiling, at the uniform velocity, enter into second deviation correcting device 25 steadily, adjust the antenna layer tension that receives, stretch it, prevent it from skidding.

In addition, a third unwinding mechanism 12 for unwinding the isolation layer on the antenna layer or on the second substrate layer is added, and an output port of the third unwinding mechanism 12 corresponds to an input port of the finished product winding mechanism 13.

Referring to fig. 8, an embodiment 4, this embodiment 4 is different from embodiment 3 in that: in this embodiment 4, the antenna hole processing mechanism processes the antenna hole by using a die cutting method, for example, the antenna hole processing mechanism 4 is a flat-pressing die-cutting machine for flat-pressing die-cutting the antenna hole 16, or a circular-knife die-cutting machine for circular-knife die-cutting the antenna hole 16.

The antenna hole processing mechanism 4 can select a flat-pressing die-cutting mechanism and/or a circular knife die-cutting mechanism to realize a die-cutting process according to actual requirements, and meets the requirements of the fully die-cut ultrahigh frequency tag antenna on the die-cutting process, particularly the requirements of the antenna hole 16 on the die-cutting process.

Referring to fig. 9, an embodiment 5, the difference between this embodiment 5 and embodiment 4 is: in this embodiment 5, a fourth printing seat 31 for printing a second positioning mark (not shown in the drawings) on the antenna layer and/or the second substrate layer by using ink is additionally provided, where the second positioning mark is used for positioning a chip during chip mounting and/or bonding; the fourth printing seat 31 is positioned between the third traction device 41 and the second die-cutting mechanism 10; in addition, a fourth traction device 43 is additionally arranged between the fourth printing seat 31 and the second die cutting mechanism 10, at the moment, an output port of the third traction device 41 corresponds to an input port of the fourth printing seat 31, an output port of the fourth printing seat 31 corresponds to an input port of the fourth traction device 43, and an output port of the fourth traction device 43 corresponds to an input port of the second die cutting mechanism 10.

In the embodiment 5, the first waste winding mechanism 11 is eliminated, that is, the output port of the first die-cutting mechanism 27 corresponds to the input port 41 of the third drawing device.

The antenna hole processing mechanism 4 processes the antenna hole 16 by adopting a punching mode.

Referring to fig. 10, embodiment 6, the difference between embodiment 6 and embodiment 5 is: in this embodiment 6, the second waste winding mechanism 26 is omitted, and the first waste winding mechanism 11 is moved to the rear of the second die-cutting mechanism 10, that is, the output port of the second die-cutting mechanism 10 corresponds to the input port of the first waste winding mechanism 11 and the input port of the second traction device 24.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings, or directly or indirectly applied to other related technical fields, are included in the same way in the protection scope of the present invention.

Claims (10)

1. An ultrahigh frequency tag antenna printing composite die cutting integrated machine relates to an ultrahigh frequency tag antenna, wherein a chip binding positioning point (14) formed by a die cutting mode and a chip binding point (15) formed by the die cutting mode are arranged on an antenna body (17) of the ultrahigh frequency tag antenna; antenna layer one side of antenna body (17) still pastes second substrate layer or first substrate layer and second substrate layer, its characterized in that: the ultrahigh frequency label antenna printing and composite die cutting integrated machine comprises a printing mechanism, a first die cutting mechanism (27), a second die cutting mechanism (10) and a tension swing roller control mechanism, wherein the printing mechanism is used for coating an adhesive on one side of an antenna layer to be processed or one side of a first substrate layer which is not adhered with the antenna layer according to the shape of an antenna body, the first die cutting mechanism is used for die-cutting a chip binding positioning point (14) and a chip binding point (15) of an ultrahigh frequency label antenna, and the second die cutting mechanism is used for die-cutting the periphery of the ultrahigh frequency label antenna.

2. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency label antenna as claimed in claim 1, wherein: the ultrahigh frequency label antenna printing and composite die cutting all-in-one machine further comprises a first unreeling mechanism (1) for unreeling an antenna layer to be processed or a composite first substrate layer to be processed, a drying mechanism (3) for drying the antenna layer coated with an adhesive according to the shape of an antenna body or a drying mechanism (3) for drying the antenna layer coated with the adhesive according to the shape of the antenna body and the composite first substrate layer, an antenna hole processing mechanism (4) for die-cutting an antenna hole (16) of the ultrahigh frequency label antenna, a composite mechanism (6) for compounding a second substrate layer and the antenna layer or compounding the second substrate layer and the first substrate layer coated with the antenna layer, a first deviation correcting device (34), a second deviation correcting device (25), a third deviation correcting device (39), a second unreeling mechanism (7) for unreeling the second substrate layer, The antenna layer after will processing and second substrate layer roll up in the lump or with the finished product winding mechanism (13) of the roll-up in the lump of antenna layer after processing and first substrate layer and second substrate layer, be used for carrying out the drive mechanism and the waste discharge mechanism that pull to the antenna layer of antenna body (17) and/or the antenna layer of compound first substrate layer and second substrate layer in the course of working of first die cutting mechanism and second die cutting mechanism (10).

3. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency tag antenna as claimed in claim 2, wherein: the printing mechanism comprises a second printing seat (29) and a third printing seat (30), wherein the second printing seat is used for printing a first positioning mark (36) and a mark block by ink on one side of the antenna layer to be processed or on one side of the first base material layer which is not adhered with the antenna layer, and the third printing seat is used for coating an adhesive on one side of the antenna layer to be processed or on one side of the first base material layer which is not adhered with the antenna layer according to the shape of the antenna body.

4. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency tag antenna as claimed in claim 3, wherein: the tension swing roller control mechanism comprises a first tension swing roller control mechanism (40); the traction mechanism comprises a first traction device (23) and a second traction device (24); the waste discharge mechanism comprises a first waste discharge winding mechanism (11) and a second waste discharge winding mechanism (26);

an output port of the first unreeling mechanism (1) corresponds to an input port of a first deviation correcting device (34), an output port of the first deviation correcting device (34) corresponds to an input port of a second printing seat (29), an output port of the second printing seat (29) corresponds to an input port of a third printing seat (30), an output port of the third printing seat (30) corresponds to an input port of a drying mechanism (3), an output port of the drying mechanism (3) corresponds to an input port of a second deviation correcting device (25), an output port of the second deviation correcting device (25) corresponds to an input port of a first traction device (23), an output port of the first traction device (23) corresponds to an input port of an antenna hole machining mechanism (4), an output port of the antenna hole machining mechanism (4) corresponds to an input port of a composite mechanism (6), an output port of the second unreeling mechanism (7) corresponds to an input port of the third deviation correcting device (39), an output port of the third deviation correcting device (39) corresponds to an input port of the composite mechanism (6), an output port of the compound mechanism (6) corresponds to an input port of the first die-cutting mechanism (27), an output port of the first die-cutting mechanism (27) corresponds to an input port of the second die-cutting mechanism (10) and an input port of the first waste discharging and winding mechanism (11), an output port of the second die-cutting mechanism (10) corresponds to an input port of the second waste discharging and winding mechanism (26) and an input port of the second traction device (24), and an output port of the second traction device (24) corresponds to an input port of the finished product winding mechanism (13);

or the output port of the first unreeling mechanism (1) corresponds to the input port of the first deviation correcting device (34), the output port of the first deviation correcting device (34) corresponds to the input port of the second printing seat (29), the output port of the second printing seat (29) corresponds to the input port of the third printing seat (30), the output port of the third printing seat (30) corresponds to the input port of the drying mechanism (3), the output port of the drying mechanism (3) corresponds to the input port of the second deviation correcting device (25), the output port of the second deviation correcting device (25) corresponds to the input port of the first traction device (23), the output port of the first traction device (23) corresponds to the input port of the antenna hole machining mechanism (4), the output port of the antenna hole machining mechanism (4) corresponds to the input port of the composite mechanism (6), the output port of the second unreeling mechanism (7) corresponds to the input port of the third deviation correcting device (39), the output port of the third deviation correcting device (39) corresponds to the input port of the composite mechanism (6), the output port of the compound mechanism (6) corresponds to the input port of the second die-cutting mechanism (10), the output port of the second die-cutting mechanism (10) corresponds to the input port of the first die-cutting mechanism (27) and the second waste discharging and winding mechanism (26), the output port of the first die-cutting mechanism (27) corresponds to the input port of the first waste discharging and winding mechanism (11) and the input port of the second traction device (24), and the output port of the second traction device (24) corresponds to the input port of the finished product winding mechanism (13).

5. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency tag antenna as claimed in claim 4, wherein: the traction mechanism further comprises a third traction device (41);

at the moment, an output port of the compound mechanism (6) corresponds to an input port of the first die-cutting mechanism (27), an output port of the first die-cutting mechanism (27) corresponds to an input port of the third traction device (41) and an input port of the first waste discharging and winding mechanism (11), an output port of the third traction device (41) corresponds to an input port of the second die-cutting mechanism (10), and an output port of the second die-cutting mechanism (10) corresponds to an input port of the second waste discharging and winding mechanism (26) and an input port of the second traction device (24);

or the output port of the compound mechanism (6) corresponds to the input port of the second die-cutting mechanism (10), the output port of the second die-cutting mechanism (10) corresponds to the input port of the third traction device (41) and the input port of the second waste discharge winding mechanism (26), the output port of the third traction device (41) corresponds to the input port of the first die-cutting mechanism (27), and the output port of the first die-cutting mechanism (27) corresponds to the input port of the first waste discharge winding mechanism (11) and the input port of the second traction device (24).

6. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency tag antenna as claimed in claim 5, wherein: the tension swing roller control mechanism also comprises a second tension swing roller control mechanism (42); the ultrahigh frequency label antenna printing composite die-cutting all-in-one machine also comprises a third unreeling mechanism (12) used for unreeling the isolating layer on the antenna layer or the second substrate layer;

at the moment, an input port of the drying mechanism (3) corresponds to an input port of a second tension swing roller control mechanism (42), and an output port of the second tension swing roller control mechanism (42) corresponds to an input port of a second deviation correcting device (25); and the output port of the third unwinding mechanism (12) corresponds to the input port of the finished product winding mechanism (13).

7. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency tag antenna as claimed in claim 6, wherein: the antenna hole processing mechanism (4) is a flat pressing die-cutting machine for flat pressing die-cutting antenna holes (16) or a circular knife die-cutting machine for circular knife die-cutting antenna holes (16).

8. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency tag antenna as claimed in claim 7, wherein: the waste discharge mechanism is a second waste discharge winding mechanism (26); the traction mechanism further comprises a fourth traction device (43); the printing mechanism further comprises a fourth printing seat (31);

at the moment, an output port of the compound mechanism (6) corresponds to an input port of the first die-cutting mechanism (27), an output port of the first die-cutting mechanism (27) corresponds to an input port of a third traction device (41), an output port of the third traction device (41) corresponds to an input port of a fourth printing seat (31), an output port of the fourth printing seat (31) corresponds to an input port of a fourth traction device (43), an output port of the fourth traction device (43) corresponds to an input port of the second die-cutting mechanism (10), and an output port of the second die-cutting mechanism (10) corresponds to an input port of the second waste discharge winding mechanism (26) and an input port of the second traction device (24);

or the output port of the compound mechanism (6) corresponds to the input port of the second die-cutting mechanism (10), the output port of the second die-cutting mechanism (10) corresponds to the input port of the third traction device (41), the output port of the third traction device (41) corresponds to the input port of the fourth printing seat (31), the output port of the fourth printing seat (31) corresponds to the input port of the fourth traction device (43), the output port of the fourth traction device (43) corresponds to the input port of the first die-cutting mechanism (27), and the output port of the first die-cutting mechanism (27) corresponds to the input port of the second waste discharging and winding mechanism (26) and the input port of the second traction device (24).

9. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency tag antenna as claimed in claim 7, wherein: the waste discharge mechanism is a first waste discharge winding mechanism (11); the traction mechanism further comprises a fourth traction device (43); the printing mechanism further comprises a fourth printing seat (31);

at the moment, an output port of the compound mechanism (6) corresponds to an input port of the first die-cutting mechanism (27), an output port of the first die-cutting mechanism (27) corresponds to an input port of a third traction device (41), an output port of the third traction device (41) corresponds to an input port of a fourth printing seat (31), an output port of the fourth printing seat (31) corresponds to an input port of a fourth traction device (43), an output port of the fourth traction device (43) corresponds to an input port of the second die-cutting mechanism (10), and an output port of the second die-cutting mechanism (10) corresponds to an input port of the first waste discharging and winding mechanism (11) and an input port of the second traction device (24);

or the output port of the compound mechanism (6) corresponds to the input port of the second die-cutting mechanism (10), the output port of the second die-cutting mechanism (10) corresponds to the input port of the third traction device (41), the output port of the third traction device (41) corresponds to the input port of the fourth printing seat (31), the output port of the fourth printing seat (31) corresponds to the input port of the fourth traction device (43), the output port of the fourth traction device (43) corresponds to the input port of the first die-cutting mechanism (27), and the output port of the first die-cutting mechanism (27) corresponds to the input port of the first waste discharging and winding mechanism (11) and the input port of the second traction device (24).

10. The integrated machine for printing, compounding and die cutting of the ultrahigh frequency label antenna as claimed in claim 8 or 9, wherein:

the first die cutting mechanism (27) is a flat-press die cutting mechanism, and the flat-press die cutting mechanism is a flat-press die cutting machine comprising at least one die cutting tool for flat-press die cutting of chip binding positioning points (14) and chip binding points (15);

or the first die-cutting mechanism (27) is composed of a circular cutter die-cutting mechanism, and the circular cutter die-cutting mechanism is a circular cutter die-cutting machine comprising at least one rolling cutter for die-cutting a chip binding positioning point (14) and a chip binding point (15) by a circular cutter;

or the first die cutting mechanism (27) is a mixed die cutting mechanism formed by mixing a flat-pressing die cutting mechanism and a circular cutter die cutting mechanism, and the mixed die cutting mechanism is a mixed die cutting mechanism comprising at least one die cutting cutter used for flat-pressing die cutting chip binding positioning points (14) or chip binding points (15) and at least one hob cutter used for circular cutter die cutting chip binding points (15) or chip binding positioning points (14);

the second die cutting mechanism (10) is a flat-pressing die cutting machine for flat-pressing the peripheral edge of the die cutting antenna body (17), or is a circular knife die cutting machine for circular knife die cutting the peripheral edge of the antenna body (17);

the first die cutting mechanism (27) is divided into a flat-pressing die cutting machine for performing flat-pressing die cutting on one of the chip binding points (15) or a circular knife die cutting machine for performing circular knife die cutting, and a flat-pressing die cutting machine for performing flat-pressing die cutting on the other chip binding point (15) and the chip binding point (14) or a circular knife die cutting machine for performing circular knife die cutting;

an exposure device is additionally arranged between the second printing seat (29) and the third printing seat (30); and/or an exposure device is arranged behind the fourth printing seat (31).

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