CN114131822B - Preparation device of electronic mark anti-counterfeiting gasket - Google Patents

Abstract

The invention relates to a preparation device of an anti-counterfeiting gasket of an electronic mark, which comprises a bracket, wherein a conveying mechanism is supported above the bracket, a plurality of gasket molds are equidistantly arranged on a carrying surface of the conveying mechanism, and a row of mold grooves are concavely arranged on the end surface of the gasket molds, which is away from the conveying mechanism. And a die cutting device, a foaming material injection device and a laser coding machine are sequentially arranged above the conveying mechanism along the advancing direction of the electronic tag bearing belt in sequence, and the foaming material injection device, the die cutting device and the laser coding machine are fixedly connected with the support. According to the invention, the electronic tag and the two-dimensional code information are associated and corresponding, so that the product has a radio frequency identification function and a mobile phone scanning verification function, and the requirements of different audiences are met.

Description

Preparation device of electronic mark anti-counterfeiting gasket

Technical Field

The invention belongs to the technical field of anti-counterfeiting, and particularly relates to a preparation device of an electronic mark anti-counterfeiting gasket.

Background

Electronic tags, i.e. RFID radio frequency identification. RFID radio frequency identification is a non-contact automatic identification technology, which automatically identifies a target object through radio frequency signals and acquires related data, and the identification work does not need manual intervention and can work in various severe environments.

The two-dimensional code has the advantages of large information capacity, wide coding range, strong fault tolerance capability, high decoding reliability, convenience in use and the like, and becomes one of the tools for bridging reality and virtual best.

In order to improve the anti-counterfeiting and counterfeiting force of white spirit products, complete the informatization management upgrading of the products and perform accurate marketing management, the electronic tags and the two-dimension codes are required to be correspondingly associated, and a new anti-counterfeiting mode and products are generated.

Disclosure of Invention

The invention aims to solve the technical problems that: the invention relates to a device for preparing an electronic identification anti-counterfeiting gasket, which overcomes the defects of the prior art, and the electronic identification anti-counterfeiting gasket is prepared by associating and corresponding the electronic label with two-dimensional code information, so that the product has a wireless radio frequency identification authentication function and a mobile phone scanning verification function at the same time, and meets the requirements of different audiences.

The invention solves the problems existing in the prior art by adopting the technical scheme that:

the anti-counterfeiting gasket with the electronic mark comprises a gasket body, wherein an electronic tag is arranged inside the gasket body, and a two-dimensional code is arranged at one end of the gasket, which is not in contact with the bottle cap.

The gasket body is made of chemical foaming materials or rubber or latex or epoxy resin.

The preparation device of the electronic mark anti-counterfeiting gasket comprises a support, wherein a conveying mechanism is supported above the support, a plurality of gasket molds are equidistantly arranged on a carrying surface of the conveying mechanism, and a row of mold grooves are concavely formed in the end surface of each gasket mold, which is away from the conveying mechanism.

And a die cutting device, a foaming material injection device and a laser coding machine are sequentially arranged above the conveying mechanism along the advancing direction of the electronic tag bearing belt in sequence, and the foaming material injection device, the die cutting device and the laser coding machine are fixedly connected with the support.

The discharge pipe openings of the foaming material injection device are arranged vertically downwards, the number of the discharge pipes is the same as that of the die grooves, and the axes of the discharge pipes and the axes of the die grooves are positioned on the same vertical plane.

The die cutting device comprises a bottom plate and a top plate which are fixedly connected with each other, the bottom surface of the bottom plate is higher than the top surface of the gasket die or is positioned on the same horizontal plane with the top surface of the gasket die, a row of die cutting holes are formed in the bottom plate, the die cutting holes are identical to the inner diameter of the die cavity, the die cutting holes and the axis of the die cavity are positioned on the same vertical plane, and a die cutter is arranged above the die cutting holes and fixedly connected with the top plate.

The laser coding machines with the same quantity as the die grooves are arranged above the conveying mechanism in a row, lenses of the laser coding machines are arranged downwards vertically, and the axes of the lenses and the axes of the die grooves are positioned on the same vertical plane.

At least two guide wheels which are rotationally connected with the support are arranged above the conveying mechanism, the two guide wheels are arranged in a staggered mode, the guide wheel at the bottom point is arranged between the foaming material injection device and the die cutting device, and the guide wheel at the high point is higher than the foaming material injection device.

The electronic tag bearing belt is contacted with the guide wheel positioned at the low point and the guide wheel positioned at the high point after passing through the die cutting device.

Preferably, the conveying mechanism comprises two annular rubber belts, and the gasket mould is arranged between the two rubber belts.

The front end and the rear end of the inside of the two rubber belts are respectively provided with a rotating shaft in a penetrating way, and the central shaft of the rotating shaft is inserted into the inner wall of the bracket.

The central shaft of one rotating shaft penetrates through the bracket and is connected with the driving end of the driving device.

Preferably, the gasket mould be fixed with on the terminal surface towards the rubber tape and place the board, place the board below and be fixed with first bull stick, first bull stick axis is parallel with the pivot axis.

The placing plate is placed above the rubber belt, a trapezoid groove is formed in the position, below the placing plate, of the top surface of the rubber belt, the first rotating rod is arranged inside the trapezoid groove, and two ends of the first rotating rod are inserted into the inner wall of the trapezoid groove.

Preferably, two ends of the die cutting device are provided with a foaming material injection device, two groups of guide wheels are arranged above the conveying mechanism, and each group of guide wheels comprises a low-level guide wheel and a high-level guide wheel.

The two groups of guide wheels are symmetrically arranged relative to the die cutting device, and the low-position guide wheels are positioned between the die cutting device and the foaming material injection device.

Preferably, the foaming material injection device comprises a main pipe, an electric control valve and discharge pipes, wherein the electric control valve is arranged at the inlet of the main pipe, and a plurality of discharge pipes are positioned below the main pipe and are in through connection with the main pipe.

And a vibrating device is arranged right below the foaming material injection device and comprises a vibrator and a mounting plate, and the vibrator is fixed above the mounting plate.

When the gasket mold is moved to a position right below the foaming material injection device, the vibrator is in contact with the gasket mold.

The main pipe is fixedly provided with a sensor bracket, two groups of second opposite-injection photoelectric sensors are arranged on the sensor bracket and the mounting plate, and the distance between the two groups of second opposite-injection photoelectric sensors is the same as the width of the gasket die.

The emitter and the receiver contained in each group of second correlation photoelectric sensors are respectively and fixedly connected with the sensor bracket and the mounting plate.

Preferably, the die cutter comprises a first shell, a second spring cavity is arranged in the middle of the inside of the first shell, and at least two third spring cavities are arranged outside the second spring cavity.

The position of the first shell inside the second spring cavity is provided with a T-shaped oil duct, the bottom plate port of the T-shaped oil duct is communicated with the top of the second spring cavity, and the top port is communicated with the side face of the third spring cavity.

And a Y-shaped oil pipe is arranged outside the first shell, and an outlet of the Y-shaped oil pipe is connected with the top of the third spring cavity in a penetrating way.

The center position below the first shell is provided with a die-cutting disc, the die-cutting disc and the die-cutting holes are coaxially arranged, the outer diameter of the die-cutting disc is the same as the inner diameter of the die-cutting holes, and the center of the die-cutting disc is provided with a through hole.

The die-cutting disc bottom is inlayed and is equipped with the guide blade, and the guide blade bottom surface is parallel with the die-cutting disc bottom surface, and the guide blade top is fixed with the second slide bar, and the second slide bar wears to establish to second spring intracavity portion through the through-hole, and second slide bar top surface is fixed with first spring holder, and the cover is equipped with the second spring on the second slide bar that is located second spring intracavity portion, and second spring chamber top surface is equipped with touch switch.

The die-cutting disc top surface is fixed with first slide bar, and inside the third spring chamber was worn to locate by first slide bar, first slide bar top surface was fixed with the piston, and the height of piston is between two to three times of die-cutting disc stroke, is located the cover and is equipped with first spring on the first slide bar of third spring chamber inside.

When the piston contacts with the top surface of the third spring cavity, the position of the interface between the T-shaped oil duct and the third spring cavity is shielded by the piston, and the distance between the bottom of the interface between the T-shaped oil duct and the third spring cavity and the top surface of the third spring cavity is the same as the stroke of the die cutting disc.

The piston periphery is equipped with the locating hole, is equipped with the through-hole that link up with the third spring chamber on the first shell, and the through-hole outside is fixed with the electro-magnet, and the telescopic link of electro-magnet passes the through-hole and contacts with the piston periphery.

When the piston moves to the uppermost part, the positioning hole is positioned at the uppermost part of the electromagnet telescopic rod, and the distance between the axis of the positioning hole and the axis of the electromagnet telescopic rod is the same as the stroke of the die cutting disc.

Preferably, a pressing plate is arranged at the front end and the rear end of the die cutter above the bottom plate.

A third sliding rod is fixed above the central position of the pressing plate, a stand column is fixed at the position of the top plate corresponding to the third sliding rod, a first spring cavity is arranged in the stand column, the tail end of the third sliding rod penetrates into the first spring cavity, and a second spring seat is fixed on the top surface of the third sliding rod.

And a third spring is sleeved on a third sliding rod positioned in the first spring cavity.

The hydraulic oil main pipe is arranged above the top plate, the hydraulic oil main pipe is respectively and fixedly connected with a pressing plate branch pipe and a die cutter branch pipe, the length of the pressing plate branch pipe is shorter than that of the die cutter branch pipe, and the pressing plate branch pipe is closer to an inlet of the hydraulic oil main pipe than that of the die cutter branch pipe.

The pressure plate branch pipe is connected with the top of the first spring cavity in a penetrating way, and the die cutter branch pipe is connected with the inlet of the Y-shaped oil pipe in a penetrating way.

The upper parts of the two sides of the pressing plate are respectively provided with a guide rod, and the tops of the guide rods penetrate through the top plate.

Preferably, the vibrator below be equipped with the low pole, the mounting panel top is equipped with the connecting rod, is connected through damping device between bottom plate and the connecting rod.

Preferably, the arc-shaped area outside of the front end of the conveying mechanism in the moving direction of the electronic tag bearing belt is covered with an arc-shaped protective cover, the radian of the arc-shaped protective cover is 90-180 degrees, and the end face of the lower side of the arc-shaped protective cover and the axis of the wrapped rotating shaft are located on the same vertical plane.

The arc-shaped protective cover is fixedly connected with the bracket.

The inside of the conveying mechanism is provided with a striking device which comprises a second rotating rod, a cylinder and an arc-shaped plate.

The second bull stick both ends wear to establish to in the support inner wall, second bull stick one end and the output shaft fixed connection of third motor, a plurality of cylinder and second bull stick mutually perpendicular and fixed connection.

The cambered surface of arc dorsad cylinder is fixed with the fourth slide bar on the terminal surface that arc and cylinder correspond, and the end of fourth slide bar wears to establish to the inside spring chamber of cylinder inside, and the end of fourth slide bar is fixed with the third spring holder, and the outside cover of fourth slide bar that is located the inside of cylinder spring holder is equipped with the fourth spring.

When the fourth slide bar is in a vertical state, the distance between the axis of the fourth slide bar and the end face of the bottom of the arc-shaped protective cover is the same as the width of the gasket die.

And a sorting conveyor belt is arranged below the beating device, is positioned below the conveying mechanism and is arranged perpendicular to the conveying mechanism.

An electronic tag reader is fixed at the upper end of the sorting conveyor belt, a first pair of photoelectric sensors is arranged under the electronic tag reader, and a transmitter and a receiver of the first pair of photoelectric sensors are respectively arranged on two sides of the sorting conveyor belt.

The sorting conveyor belt is fixed with electric putter in the side, and electric putter is located the front end of electronic tag reader, and the spaced distance between electric putter and the electronic tag reader is the same with the distance between two adjacent die cavities on the gasket mould.

The other side of the sorting conveyor belt, which corresponds to the electric push rod, is fixedly provided with an inclined plate which is arranged obliquely downwards, and the width of the inclined plate is larger than the inner diameter of the die cavity.

Compared with the prior art, the invention has the beneficial effects that:

(1) The electronic tag and the two-dimensional code information are associated and correspond, so that the product has a radio frequency identification authentication function and a mobile phone scanning authentication function, and the requirements of different audiences are met.

(2) The gasket is plugged into the bottle cap, the electronic tag information and the two-dimensional code information are hidden inside the bottle cap, the bottle cap cannot be transferred to be used before being opened, and the two-dimensional code faces the inner side of the bottle during use and is used for scanning after the bottle cap is opened, so that the bottle cap can be used for rewarding and promoting.

(3) The electronic tag is arranged inside the gasket, so that the electronic tag is prevented from being damaged in the using process.

Drawings

The invention will be further described with reference to the drawings and examples.

FIG. 1 is a view showing the external appearance of the device for preparing the anti-counterfeiting gasket for the electronic mark,

FIG. 2 is a view showing the appearance of the device for manufacturing the anti-counterfeiting gasket with the electronic tag after the electronic tag tape is removed,

figure 3 is a longitudinal sectional view of the device for preparing the anti-counterfeiting gasket of the electronic mark,

figure 4 is a transverse cross-sectional view of the electronic identification anti-counterfeiting gasket manufacturing device of the invention,

figure 5 is a transverse cross-sectional view of the electronic mark anti-counterfeiting gasket preparation device according to the invention at the position of the striking device,

figure 6 is a transverse cross-sectional view of the electronic mark anti-counterfeiting gasket preparation device of the invention at a laser coding machine,

figure 7 is an enlarged view of a portion of figure 3 at a,

figure 8 is a diagram of the external appearance of the conveying mechanism of the electronic mark anti-counterfeiting gasket preparation device,

figure 9 is a transverse cross-sectional view of the conveying mechanism of the electronic identification anti-counterfeiting gasket preparation device of the invention,

Figure 10 is an enlarged view of a portion of figure 9 at B,

figure 11 is a longitudinal cross-sectional view of the conveying mechanism of the electronic mark anti-counterfeiting gasket preparation device of the invention,

figure 12 is an enlarged view of a portion of figure 11 at C,

FIG. 13 is a schematic view of the striking device of the electronic mark anti-counterfeiting gasket manufacturing device according to the present invention,

figure 14 is a cross-sectional view of the striking device of the electronic identification anti-counterfeiting gasket manufacturing device of the present invention,

figure 15 is an enlarged view of a portion of figure 12 at D,

FIG. 16 is a diagram showing the outline of a roll-over plate of the apparatus for manufacturing an anti-counterfeit gasket for electronic identification of the present invention,

FIG. 17 is a schematic view of the foaming material injecting device of the electronic mark anti-counterfeiting gasket manufacturing device according to the present invention,

figure 18 is an exploded view of a vibration device of the electronic identification anti-counterfeiting gasket manufacturing device according to the present invention,

figure 19 is a diagram showing the appearance of a sorting conveyor belt of the electronic mark anti-counterfeiting gasket preparation device,

figure 20 is an enlarged view of a portion of figure 19 at E,

figure 21 is an outline view of a die-cutting device of the electronic mark anti-counterfeiting gasket preparation device,

figure 22 is a partial cross-sectional view of a die-cutting device of the electronic identification anti-counterfeiting gasket manufacturing device according to the invention,

figure 23 is a transverse cross-sectional view of a die-cutting device of the electronic identification anti-counterfeiting gasket manufacturing device according to the invention,

figure 24 is a partial cross-sectional view of a die cutter housing of the electronic identification anti-counterfeit gasket preparation device of the present invention,

Figure 25 is an exploded view of a die cutter of the electronic identification anti-counterfeiting gasket manufacturing device according to the present invention,

FIG. 26 is a schematic diagram of the oiling station of the electronic mark anti-counterfeiting gasket manufacturing device according to the invention,

figure 27 is a longitudinal cross-sectional view of the oiling station of the electronic identification anti-counterfeiting gasket manufacturing device of the present invention,

figure 28 is a transverse cross-sectional view of the oiling station of the electronic identification anti-counterfeiting gasket manufacturing device of the present invention,

fig. 29 is a cross-sectional view of the spline of the oiling station of the electronic mark anti-counterfeiting gasket preparation device.

In the figure: 1-bracket, 2-conveying mechanism, 201-rubber belt, 2011-trapezoid groove, 202-rotating shaft, 203-driving device, 3-gasket die, 301-die groove, 302-groove, 303-placing plate, 304-first rotating rod, 4-foaming material injection device, 401-main pipe, 402-electric control valve, 403-discharging pipe, 404-sensor bracket, 5-die cutting device, 501-bottom plate, 5011-die cutting hole, 502-top plate, 5021-upright post, 5022-first spring cavity, 503-die cutter, 5031-first shell, 50311-second spring cavity, 50312-third spring cavity, 50313-T-shaped oil duct, 5032-Y-type oil pipe, 5033-electromagnet, 5034-die cutting disc, 50341-through hole 50342-first slide bar, 50343-piston, 503431-pilot hole, 50344-first spring, 5035-guide piece, 50351-second slide bar, 50352-second spring, 50353-first spring seat, 504-platen, 5041-third slide bar, 5042-third spring, 5043-second spring seat, 5044-guide bar, 505-hydraulic oil main pipe 5051-platen manifold, 5052-die cutter manifold, 506-touch switch, 6-oiling device, 601-second housing, 6011-oil chamber, 6012-control chamber, 602-sponge, 603-connecting rod, 6031-spline, 604-rotating sleeve, 605-timing belt, 606-pulley, 6061-first motor, 607-screw, 6071-second motor, 608-clamping plate, 609-supporting frame, 7-laser coding machine, 8-vibrating device, 801-vibrator, 802-bottom rod, 803-damping device, 8031-center block, 8032-lantern ring, 804-connecting rod, 805-mounting plate, 9-sorting conveyor belt, 901-electronic tag reader, 902-sloping plate, 903-electric push rod, 904-first pair of photoelectric sensors, 10-horizontal plate, 11-guide wheel, 1101-electronic tag carrier belt, 12-arc protection cover, 13-beating device, 1301-second rotating rod, 1302-third motor, 1303-cylinder, 1304-arc plate, 13041-fourth sliding rod, 13042-third spring seat, 1305-fourth spring, 14-turnover plate, 1401-flat plate, 1402-side plate, 1403-rotating shaft, 1404-fourth motor, 15-second pair of photoelectric sensors.

Detailed Description

Certain terms are used throughout the description and claims to refer to particular components. Those of skill in the art will appreciate that a hardware manufacturer may refer to the same component by different names. The description and claims do not take the form of an element differentiated by name, but rather by functionality. As used throughout the specification and claims, the word "comprise" is an open-ended term, and thus should be interpreted to mean "include, but not limited to. By "substantially" is meant that within an acceptable error range, a person skilled in the art is able to solve the technical problem within a certain error range, substantially achieving the technical effect.

In the description of the present invention, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "front", "rear", "left", "right", "horizontal", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

The apparatus for manufacturing the anti-counterfeiting gasket for electronic mark according to the present invention will be described in further detail with reference to the accompanying drawings, but is not intended to limit the invention.

The anti-counterfeiting gasket with the electronic mark comprises a gasket body, wherein an electronic tag is arranged inside the gasket body, and a two-dimensional code is arranged at one end of the gasket, which is not in contact with the bottle cap. The electronic tags can be directly wrapped by the gasket body or can be arranged in a layered mode, namely, one layer of electronic tag is clamped between two layers of gaskets.

The gasket body is made of chemical foaming materials or rubber or latex or epoxy resin, and the chemical foaming materials are adopted in the embodiment.

The preparation device of the electronic mark anti-counterfeiting gasket comprises a bracket 1, wherein the bracket 1 comprises two side plates, supporting legs fixed below the side plates and a connecting plate fixedly connected between the supporting legs.

A conveying mechanism 2 is supported above the bracket 1, and a plurality of gasket molds 3 are equidistantly arranged on the carrying surface of the conveying mechanism 2. A row of die grooves 301 are concaved inwards on the end face of the gasket die 3, which is far away from the conveying mechanism 2, each row of die grooves 301 comprises a plurality of die grooves 301, and the number of the die grooves 301 is more than or equal to 3 in the implementation.

The conveying mechanism 2 comprises two annular rubber belts 201 which are arranged in parallel, and the gasket mould 3 is arranged between the two rubber belts 201.

Two rotating shafts 202 are respectively arranged at the front end and the rear end of the inside of the two rubber belts 201 in a penetrating way, the central shaft of each rotating shaft 202 is inserted into the inner wall of the side plate of the support 1, and the central shaft of one rotating shaft 202 penetrates through the support 1 to be connected with the driving end of the driving device 203. The driving device 203 comprises a motor, a speed reducer and a synchronous belt, wherein the output end of the motor is connected with the input end of the speed reducer, the output end of the speed reducer and the tail end of the central shaft of the rotating shaft 202 are respectively provided with a belt pulley, and the synchronous belt is sleeved between the two belt pulleys. The driving device 203 drives the rotating shaft 202 to rotate, and the gasket mould 3 above the driving device is driven to move by the rubber belt 201.

Since the two ends of the rubber belt 201 are semicircular, in order to facilitate the turning of the gasket mold 3, in this embodiment, the end surface of the gasket mold 3 facing the rubber belt 201 is fixed with a placement plate 303. A first rotating rod 304 is fixed below the placing plate 303, and the axis of the first rotating rod 304 is parallel to the axis of the rotating shaft 202.

The placing plate 303 is placed above the rubber belt 201, a trapezoid groove 2011 is formed in the position, below the placing plate 303, of the top surface of the rubber belt 201, a region, fixedly connected with the placing plate 303, of the middle of the first rotating rod 304 is arranged inside the trapezoid groove 2011, and two ends of the first rotating rod 304 are inserted into the inner wall of the trapezoid groove 2011.

Since the trapezoidal groove 2011 has an isosceles trapezoid shape in cross section perpendicular to the axis of the first rotating lever 304, when the gasket mold 3 is moved to the end of the rubber belt 201, the first rotating lever 304 rotates, and the placing plate 303 does not come into line contact with the rubber belt 201, and interference does not occur.

The outer part of the semicircular area of the rubber belt 201 on the conveying mechanism 2, which is positioned at the front end of the electronic tag bearing belt 1101 in the moving direction, is covered with an arc-shaped protective cover 12, and the radian of the arc-shaped protective cover 12 is 90-180 degrees. The gasket mold 3 does not collide with the arc-shaped shield 12 while moving inside the semicircular region of the rubber belt 201, and the gap between it and the arc-shaped shield 12 is smaller than the depth of the die cavity 301.

The lower end surface of the arc-shaped protective cover 12 and the axis of the rotating shaft 202 wrapped by the arc-shaped protective cover 12 are positioned on the same vertical plane, and the arc-shaped protective cover 12 is fixedly connected with the bracket 1.

The arc-shaped protective cover 12 prevents the formed gasket from falling off from the inside of the die cavity 301 in the overturning process of the gasket die 3. Only when the gasket mold 3 is turned 180 degrees, the opening of the cavity 301 is arranged vertically downward, and the molded gasket can be released.

In order to promote the falling-off of the gasket, the striking device 13 is provided inside the transfer mechanism 2, the striking device 13 comprising a second rotating rod 1301, a cylinder 1303 and an arc 1304.

Two ends of the second rotating rod 1301 penetrate into the inner wall of the bracket 1, one end of the second rotating rod 1301 is fixedly connected with an output shaft of the third motor 1302, and the third motor 1302 is fixedly connected with the bracket 1. A plurality of cylinders 1303 are perpendicular to the second rotating rod 1301 and fixedly connected.

The cambered surface of arc 1304 is facing away from cylinder 1303, is fixed with fourth slide bar 13041 on the arc 1304 and the terminal surface that the cylinder 1303 corresponds, and the spring chamber inside to the cylinder 1303 is worn to establish by fourth slide bar 13041 end, and fourth slide bar 13041 end is fixed with third spring holder 13042, is located the outside cover of fourth slide bar 13041 of cylinder 1303 spring holder inside and is equipped with fourth spring 1305.

When the fourth slide bar 13041 is in a vertical state, the distance between the axis of the fourth slide bar 13041 and the end face of the bottom of the arc-shaped protective cover 12 is the same as the width of the gasket mould 3.

Under the urging of the fourth spring 1305, the distance between the center of the arc bottom surface of the arc plate 1304 and the axis of the second rotating rod 1301 is greater than the distance between the axis of the second rotating rod 1301 and the bottom surface of the gasket mold 3 below the same, and is smaller than the distance between the axis of the second rotating rod 1301 and the top surface of the gasket mold 3 below the same. The vertical distance between the lowest point of the arcuate bottom surface of the arcuate plate 1304 and the end is less than the thickness of the gasket mold 3.

The second rotating rod 1301 rotates to knock the arc plate 1304 against the gasket mold 3, causing the gasket formed inside to fall off. The arc plate 1304 presses the fourth spring 1305 to shorten the interval between it and the second rotating rod 1301 after knocking, so that the gasket mold 3 does not generate dryness on its rotation.

A sorting conveyor belt 9 is arranged below the striking device 13, and the sorting conveyor belt 9 is in the prior art. The sorting conveyor 9 is located below the conveyor 2, the sorting conveyor 9 being arranged perpendicular to the conveyor 2.

An electronic tag reader 901 is fixed at the upper end of the sorting conveyor belt 9, a first pair of photoelectric sensors 904 are arranged under the electronic tag reader 901, and a transmitter and a receiver of the first pair of photoelectric sensors 904 are respectively arranged on two sides of the sorting conveyor belt 9.

An electric push rod 903 is fixed on the side face of the sorting conveyor belt 9, the electric push rod 903 is located at the front end of the electronic tag reader 901, and the distance between the electric push rod 903 and the electronic tag reader 901 is the same as the distance between two adjacent die cavities 301 on the gasket die 3.

The sorting conveyor 9 is fixed with a sloping plate 902 arranged obliquely downward on the other side corresponding to the electric push rod 903, and the width of the sloping plate 902 is larger than the inner diameter of the die cavity 301.

The formed gasket falls onto the sorting conveyor belt 9, and the sorting conveyor belt 9 moves with it, and when moving to directly under the electronic tag reader 901, the first pair of photoelectric sensors 904 are blocked, a signal is detected, the electronic tag reader 901 is turned on, and the electronic tag inside the gasket is identified. If the identification is impossible, the product is defective. When the gasket moves to the position of the electric push rod 903, the electric push rod 903 is energized, pushing the gasket into the swash plate 902 and sliding down into the waste collection box. Since the distance between the electric push rod 903 and the electronic tag reader 901 is fixed, the time when the waste gasket moves from the electronic tag reader 901 to the electric push rod 903 can be known, and thus in this embodiment, the control switch of the electric push rod 903 only needs to be a time delay switch.

Besides the requirement for detecting the quality of the electronic tag in the gasket, the integrity of the two-dimensional code on the surface of the gasket is also required to be checked. Therefore, in this embodiment, a turnover plate 14 is disposed between the gasket mold 3 and the sorting conveyor 9, the width of the turnover plate 14 is larger than the outer diameter of the gasket, the turnover plate 14 includes a flat plate 1401 horizontally disposed and two protruding side plates 1402 at two ends of the flat plate 1401 in the width direction, two rotating shafts 1403 are respectively fixed at the center positions of two ends of the flat plate 1401 in the length direction, the rotating shafts 1403 are rotatably connected with the bracket 1, one rotating shaft 1403 is fixedly connected with an output shaft of a fourth motor 1404, and the fourth motor 1404 is fixedly connected with the bracket 1.

The gasket on the gasket mould 3 is dropped vertically onto the flat plate 1401, the flat plate 1401 is rotated 180 °, and the gasket is dropped vertically onto the sorting conveyor 9. Therefore, the gasket is turned over, and the side carved with the two-dimensional code faces upwards. And judging the completion degree and the quality of the two-dimensional code through manual visual inspection, and sorting products.

Since the gasket mold 3 moved above the rubber belt 201 is required to be subjected to operations such as material injection, the gasket mold 3 is required to run smoothly and move in a straight line, and no up-and-down fluctuation occurs during the movement. Thus, a horizontal plate 10 fixedly connected with the bracket 1 is arranged between the two rubber belts 201, the horizontal plate 10 is positioned above the axis of the rotating shaft 202, and the top surface of the horizontal plate 10 is contacted with the bottom surface of the gasket mould 3 positioned above the horizontal plate 10.

The two ends of the horizontal plate 10 are respectively provided with an inclined plane, so that the gasket mould 3 can not interfere when the horizontal plate 10 is arranged up and down.

A die cutting device 5, a foaming material injection device 4 and a laser coding machine 7 are sequentially arranged above the conveying mechanism 2 along the advancing direction of the electronic tag bearing belt 1101, and the foaming material injection device 4, the die cutting device 5 and the laser coding machine 7 are fixedly connected with the bracket 1.

At least two guide wheels 11 which are rotationally connected with the bracket 1 are arranged above the conveying mechanism 2, the two guide wheels 11 are arranged in a staggered mode, the guide wheel 11 positioned at the bottom point is arranged between the foaming material injection device 4 and the die cutting device 5, and the guide wheel 11 positioned at the high point is higher than the foaming material injection device 4.

The electronic label bearing belt 1101 is contacted with the guide wheel 11 at the low point and the guide wheel 11 at the high point after passing through the die cutting device 5. In this way, the electronic tag bearing belt 1101 is cut off from the electronic tag above the electronic tag bearing belt 1101 by the die cutting device 5, then the rest materials are guided by the guide wheels 11 at the low point, move upwards and then move horizontally after being guided by the guide wheels 11 at the high point, so that the electronic tag bearing belt 1101 avoids the foaming material injection device 4, and the foaming material injection device 4 cannot be dry.

In this embodiment, the manufactured gasket is provided with foaming material layers at the upper and lower ends of the electronic tag, so in this embodiment, two foaming material injection devices 4 are provided at the two ends of the die cutting device 5, two sets of guide wheels 11 are provided above the conveying mechanism 2, and each set of guide wheels 11 includes a low-level guide wheel 11 and a high-level guide wheel 11.

The two groups of guide wheels 11 are symmetrically arranged relative to the die cutting device 5, and the lower guide wheel 11 is positioned between the die cutting device 5 and the foaming material injection device 4.

The foaming material injection device 4 comprises a main pipe 401, an electric control valve 402 and discharge pipes 403, wherein the electric control valve 402 is arranged at the inlet of the main pipe 401, and a plurality of discharge pipes 403 are arranged below the main pipe 401 and are communicated with the main pipe 401. The inlet of the main pipe 401 is communicated with the main pipe of the foaming material in the factory.

The discharge pipes 403 are arranged vertically downward, the number of the discharge pipes 403 is the same as that of the cavities 301, the axes of the discharge pipes 403 and the axes of the cavities 301 are on the same vertical plane, and when the gasket mold 3 is moved to the position right below the foaming material injecting device 4, the axes of the discharge pipes 403 and the axes of the cavities 301 are on the same vertical line.

In order to fill the foaming material into the cavity 301, the upper end surface of the foaming material is flush and the inside is dense. In this embodiment, a vibrator 8 is added.

The vibration device 8 is located directly below the foaming material injection device 4, and the vibration device 8 includes a vibrator 801 and a mounting plate 805, and the vibrator 801 adopts the prior art. The lower rod 802 is arranged below the vibrator 801, the connecting rod 804 is arranged above the mounting plate 805, and the bottom plate 802 is connected with the connecting rod 804 through the damping device 803. The damping device 803 includes a rubber-supported center block 8031 and a collar 8032, the center block 8031 is inserted into the collar 8032, the center block 8031 is fixedly connected with the lower rod 802, and the sleeve 8032 is fixedly connected with the connecting rod 804.

In order to further increase the contact area between the vibrator 801 and the gasket mold 3, the bottom surface of the gasket mold 3 is recessed with a groove 302, and the width of the groove 302 is the same as the width of the vibrator 801. When the spacer mold 3 is moved to just above the vibrator 801, the vibrator 801 is inserted into the inside of the groove 302, contacting the inner wall of the groove 302. To facilitate insertion of vibrator 801, the front end port of groove 302 is provided with a chamfer.

The header 401 is fixed with a sensor bracket 404, two groups of second pair of photoelectric sensors 15 are arranged on the sensor bracket 404 and the mounting plate 805, and the distance between the two groups of second pair of photoelectric sensors 15 is the same as the width of the gasket die 3.

In order to accelerate the setting of the material injected into the mold cavity 301, the front end of the foam injection device 4 (i.e., the front end of the running direction of the electronic tag bearing belt 1101) is provided with a drying system, which is generally used for initiating the rapid setting thereof by hot air or baking, and the drying system adopts the prior art.

The transmitters and receivers comprised by each set of second correlation photosensors 15 are fixedly connected to the sensor holder 404 and the mounting plate 805, respectively.

Two sets of second pair of photoelectric sensors 15 detect whether the mat mold 3 enters between them.

The die cutting device 5 comprises a bottom plate 501 and a top plate 502 which are fixedly connected with each other, the bottom surface of the bottom plate 501 is higher than the top surface of the gasket die 3 or is positioned on the same horizontal plane with the top surface of the gasket die 3, a row of die cutting holes 5011 are arranged on the bottom plate 501, and the inner diameter of the die cutting holes 5011 and the inner diameter of the die groove 301 are the same or smaller than the inner diameter of the die groove 301. The die cutting hole 5011 and the axis of the die cavity 301 are positioned on the same vertical plane, a die cutter 503 is arranged above the die cutting hole 5011, and the die cutter 503 is fixedly connected with the top plate 502.

The laser coding machines 7 with the same number as the die grooves 301 are arranged above the conveying mechanism 2 in a row, lenses of the laser coding machines 7 are arranged vertically downwards, and the axes of the lenses and the axes of the die grooves 301 are positioned on the same vertical plane. The laser coding machine 7 is of the prior art.

The gasket die 3 is moved under the bottom plate 501 so that the axis of the die-cutting hole 5011 coincides with the axis of the cavity 301. The electronic label carrier tape 1101 is moved from above the base plate 501 such that the electronic labels on the electronic label carrier tape 1101 are positioned between the die cutter 503 and the die cut holes 5011. The movement of the rubber tape 201 is then stopped, the die cutter 503 cuts off the electronic label, and the electronic label slides down the die-cutting hole 5011 into the die cavity 301.

The gasket mold 3 with the electronic tag is continuously moved forward and is moved between the two groups of second opposite-shooting photoelectric sensors, and at the moment, the driving device 203 is powered off, so that the rubber belt 201 stops rotating. The discharge pipe 403 is located right above the cavity 301, and a foaming material is injected into the interior to cover the electronic chip.

Then the gasket mould 3 continues to move forward and moves to the position below the laser coding machine 7, at the moment, the foaming material is hardened, a gasket is formed together with the electronic tag, and the laser coding machine 7 is used for marking a two-dimensional code above the gasket.

For better die cutting and blanking, in this embodiment, the die cutter 503 includes a first housing 5031. A second spring cavity 50311 is provided in the middle of the interior of the first housing 5031, and at least two third spring cavities 50312 are provided outside the second spring cavity 50311.

A T-shaped oil duct 50313 is arranged in the first housing 5031 above the second spring cavity 50311, a bottom plate port of the T-shaped oil duct 50313 is connected with the top of the second spring cavity 50311 in a penetrating manner, and a top port of the T-shaped oil duct is connected with the side surface of the third spring cavity 50312 in a penetrating manner.

The first housing 5031 is provided with a Y-shaped oil pipe 5032, and an outlet of the Y-shaped oil pipe 5032 is communicated with the top of the third spring cavity 50312.

A die-cutting disc 5034 is arranged at the center position below the first shell 5031, the die-cutting disc 5034 and the die-cutting hole 5011 are coaxially arranged, the outer diameter of the die-cutting disc 5034 is identical to the inner diameter of the die-cutting hole 5011, and a through hole 50341 is formed in the center of the die-cutting disc 5034. The die cut tray 5034 is positioned uppermost with a spacing between its bottom surface and the top surface of the die cut holes 5011 that is greater than the thickness of the electronic label carrier tape 1101.

The bottom of the die-cutting disc 5034 is inlaid with a guide plate 5035, the bottom surface of the guide plate 5035 is parallel to the bottom surface of the die-cutting disc 5034, a second slide rod 50351 is fixed above the guide plate 5035, the second slide rod 50351 is penetrated into the second spring cavity 50311 through a through hole 50341, the top surface of the second slide rod 50351 is fixedly provided with a first spring seat 50353, a second spring 50352 is sleeved on a second slide rod 50351 positioned in the second spring cavity 50311, and the top surface of the second spring cavity 50311 is provided with a touch switch 506.

The top surface of the die cutting disc 5034 is fixed with a first slide bar 50342, the first slide bar 50342 penetrates through the third spring cavity 50312, the top surface of the first slide bar 50342 is fixed with a piston 50343, the height of the piston 50343 is between two and three times of the stroke of the die cutting disc 5034, and a first spring 50344 is sleeved on the first slide bar 50342 positioned in the third spring cavity 50312.

When the piston 50343 contacts the top surface of the third spring cavity 50312, the position of the interface between the T-shaped oil duct 50313 and the third spring cavity 50312 is blocked by the piston 50343, and the distance between the bottom of the interface between the T-shaped oil duct 50313 and the third spring cavity 50312 and the top surface of the third spring cavity 50312 is the same as the stroke of the die-cutting disc 5034.

The piston 50343 has a positioning hole 503431 on its circumferential surface, a through hole connected with the third spring cavity 50312 is formed in the first housing, an electromagnet 5033 is fixed outside the through hole, and a telescopic rod of the electromagnet 5033 passes through the through hole to contact with the circumferential surface of the piston 50343.

When the piston 50343 is moved to the uppermost position, the positioning hole 503431 is positioned at the uppermost position of the telescopic rod of the electromagnet 5033, and the distance between the axis of the positioning hole 503431 and the axis of the telescopic rod of the electromagnet 5033 is the same as the stroke of the die cutting disc 5034.

When in use, hydraulic oil flows into the third spring cavity 50312 through the Y-shaped oil pipe 5032, pushes the piston 50343 to move downwards, and further pushes the die-cutting disc 5034 to move downwards to die-cut the electronic tag bearing belt 1101 between the die-cutting disc 5034 and the die-cutting hole 5011. In order to control the depth of the die cutting disc 5034 into the die cutting hole 5011, a limit retainer ring can be sleeved on the die cutting disc 5034.

When the piston 50343 moves down, the electromagnet 5033 is energized, the telescopic rod thereof abuts against the circumferential surface of the piston 50343, and when the positioning hole 503431 of the piston 50343 moves down to be the same as the front end of the telescopic rod of the electromagnet 5033, the telescopic rod is inserted into the positioning hole 503431. The front end of the telescopic rod can also be made into an arc shape or an inclined plane, so that as long as the bottom of the positioning hole 503431 is contacted with the telescopic rod, the telescopic rod is inserted into the positioning hole 503431 under the pushing of the electromagnet 5033, and the piston 50343 is further promoted to move downwards. After the telescopic rod is completely inserted into the positioning hole 503431, the top surface of the piston 50343 exposes the interface of the T-shaped oil duct 50313, hydraulic oil in the third spring cavity 50312 flows into the second spring cavity 50311 through the T-shaped oil duct 50313, the guide plate 5035 is pushed to move down, and the guide plate 5035 is pushed to push the electronic tag to enter the die cavity 301.

After shearing is completed, the hydraulic oil is decompressed, the guide plate 5035 moves upwards under the pushing of the spring, the hydraulic oil in the second spring cavity 50311 flows into the third spring cavity 50312, after the top surface of the first spring seat 50353 collides with the touch switch 506, the electromagnet 5033 is powered off, the telescopic rod is retracted, and the die cutting disc 5034 is reset under the pushing of the spring.

In order to fix the electronic label bearing belt 1101 during the die cutting process, a pressing plate 504 is respectively disposed on the front and rear ends of the die cutter 503 above the bottom plate 501.

A third sliding rod 5041 is fixed above the central position of the pressing plate 504, a vertical column 5021 is fixed at a position of the top plate 502 corresponding to the third sliding rod 5041, a first spring cavity 5022 is arranged in the vertical column 5021, the tail end of the third sliding rod 5041 is arranged inside the first spring cavity 5022 in a penetrating mode, and a second spring seat 5043 is fixed on the top surface of the third sliding rod 5041.

A third spring 5042 is sleeved on the third sliding rod 5041 positioned in the first spring cavity 5022. Two guide rods 5044 are arranged above two sides of the pressing plate 504, and the tops of the guide rods 5044 penetrate through the top plate 502.

A hydraulic oil main pipe 505 is arranged above the top plate 502, a pressing plate branch pipe 5051 and a die cutter branch pipe 5052 are respectively connected on the hydraulic oil main pipe 505 in a penetrating mode, the length of the pressing plate branch pipe 5051 is shorter than that of the die cutter branch pipe 5052, and the pressing plate branch pipe 5051 is closer to an inlet of the hydraulic oil main pipe 505 than that of the die cutter branch pipe 5052.

The platen branch 5051 is connected with the top of the first spring cavity 5022 in a penetrating manner, the die cutter branch 5052 is connected with the inlet of the Y-shaped oil pipe 5032 in a penetrating manner, and since the length of the platen branch 5051 is shorter than that of the die cutter branch 5052 and is closer to the inlet of the hydraulic oil main pipe 505, after hydraulic oil is injected into the hydraulic oil main pipe 505, the platen 504 moves downwards to press the electronic tag bearing belt 1101, and then the die cutter 503 starts to act to perform die cutting.

The inlet of the hydraulic oil main pipe 505 is communicated with a hydraulic station, and the hydraulic station adopts the prior art.

In order to facilitate the detachment of the gasket mold cavity 301, when the foaming material is not injected into the mold cavity 301, the lubricating oil is applied to the inside of the mold cavity 301.

In this embodiment, the lubricating oil is applied by using an oiling device 6, and the oiling device 6 is disposed below the conveying mechanism 2. The oiling device 6 comprises a second housing 601 with an open upper end, and the second housing 601 is fixedly connected with the bracket 1. The second housing 601 is internally provided with a partition plate, the partition plate divides the second housing 601 into an upper layer and a lower layer, the upper layer is an oil cavity 6011, the lower layer is a control cavity 6012, and lubricating oil is added in the oil cavity 6011.

The oil cavity 6011 is internally provided with cylindrical sponges 602 which are equal in number to the die grooves 301, the sponges 602 are in one-to-one correspondence with the die grooves 301, and lubricating oil is smeared on the inner walls and the bottom surfaces of the sponges. A connecting rod 603 is fixed at the axis of the sponge 602. The connecting rod 603 is inserted into the control chamber 6012 and is fixed with a spline 6031.

A plurality of rotating sleeves 604 are arranged vertically in the control cavity 6012, and the rotating sleeves 604 are supported by a supporting frame 609. The inside of the rotating sleeve 604 is provided with spline grooves, and the spline 6031 is inserted into the spline grooves in the rotating sleeve 604 and can move up and down.

One end of the control cavity 6012 is provided with a belt pulley 606, each rotating sleeve 604 is also provided with a belt pulley, and the belt pulley 606 and the belt pulley of the rotating sleeve 604 are sleeved with a synchronous belt 605. The pulley 606 is fixedly connected to the output shaft of the first motor 6061.

All connecting rods 603 penetrate through a clamping plate 608, clamping rings are respectively sleeved on the upper side and the lower side of the clamping plate 608, and the connecting rods 603 are rotationally connected with the clamping plate 608. One end of the clamping plate 608 is in threaded connection with a screw 607 which is vertically arranged, and the end of the screw 607 is connected with the output shaft of the second motor 6071.

The preparation device of the electronic mark anti-counterfeiting gasket is also provided with an electric control cabinet, and all electric parts contained in the preparation device of the electronic mark anti-counterfeiting gasket are electrically connected with the electric control cabinet.

When one shim mold 3 moves between the two sets of second correlation photosensors 15, the transfer mechanism 2 stops operating. At this time, the discharge pipe 403 is coaxial with the cavity 301 of the gasket mold 3 below it, the cavity 301 of the gasket mold 3 below the die cutting device 5 is coaxial with the die cutting hole 5011, the lens of the laser marking machine 7 faces the cavity 301 below it, and the cavity 301 of the gasket mold 3 above the oiling device 6 is coaxial with the sponge 602.

The front and rear ends of the electronic tag bearing belt 1101 are respectively connected with a feeder and a coiling machine, which are all the prior art.

The embodiments of the present invention have been described in detail with reference to the drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present invention.

Claims (7)

1. The preparation facilities of electronic mark anti-fake gasket, its characterized in that:

comprises a bracket (1), a conveying mechanism (2) is supported above the bracket (1), a plurality of gasket moulds (3) are equidistantly arranged on the carrying surface of the conveying mechanism (2), a row of mould grooves (301) are concavely arranged on the end surface of the gasket moulds (3) deviating from the conveying mechanism (2),

a die cutting device (5), a foaming material injection device (4) and a laser coding machine (7) are sequentially arranged above the conveying mechanism (2) along the advancing direction of the electronic tag bearing belt (1101), the foaming material injection device (4), the die cutting device (5) and the laser coding machine (7) are fixedly connected with the bracket (1),

the openings of the discharge pipes (403) of the foaming material injection device (4) are vertically downwards arranged, the number of the discharge pipes (403) is the same as that of the die grooves (301), the axes of the discharge pipes (403) and the axes of the die grooves (301) are positioned on the same vertical plane,

The die cutting device (5) comprises a bottom plate (501) and a top plate (502) which are fixedly connected with each other, the bottom surface of the bottom plate (501) is higher than the top surface of the gasket die (3) or is positioned on the same horizontal plane with the top surface of the gasket die (3), a row of die cutting holes (5011) are arranged on the bottom plate (501), the inner diameters of the die cutting holes (5011) and the die grooves (301) are the same, the axes of the die cutting holes (5011) and the die grooves (301) are positioned on the same vertical plane, a die cutter (503) is arranged above the die cutting holes (5011), the die cutter (503) is fixedly connected with the top plate (502),

the die cutter (503) comprises a first shell (5031), a second spring cavity (50311) is arranged in the middle of the inside of the first shell (5031), at least two third spring cavities (50312) are arranged outside the second spring cavity (50311),

a T-shaped oil duct (50313) is arranged in the first shell (5031) and positioned above the second spring cavity (50311), a bottom plate port of the T-shaped oil duct (50313) is communicated with the top of the second spring cavity (50311), a top port is communicated with the side surface of the third spring cavity (50312),

a Y-shaped oil pipe (5032) is arranged outside the first shell (5031), an outlet of the Y-shaped oil pipe (5032) is communicated with the top of the third spring cavity (50312),

A die-cutting disc (5034) is arranged at the center position below the first shell (5031), the die-cutting disc (5034) and the die-cutting hole (5011) are coaxially arranged, the outer diameter of the die-cutting disc (5034) is the same as the inner diameter of the die-cutting hole (5011), a through hole (50341) is arranged at the center of the die-cutting disc (5034),

a guide plate (5035) is inlaid at the bottom of the die cutting disc (5034), the bottom surface of the guide plate (5035) is parallel to the bottom surface of the die cutting disc (5034), a second slide rod (50351) is fixed above the guide plate (5035), the second slide rod (50351) is penetrated into the second spring cavity (50311) through a through hole (50341), a first spring seat (50353) is fixed on the top surface of the second slide rod (50351), a second spring (50352) is sleeved on the second slide rod (50351) positioned in the second spring cavity (50311), a touch switch (506) is arranged on the top surface of the second spring cavity (50311),

the top surface of the die cutting disc (5034) is fixed with a first slide bar (50342), the first slide bar (50342) is penetrated in the third spring cavity (50312), the top surface of the first slide bar (50342) is fixed with a piston (50343), the height of the piston (50343) is between two and three times of the stroke of the die cutting disc (5034), a first spring (50344) is sleeved on the first slide bar (50342) positioned in the third spring cavity (50312),

When the piston (50343) is contacted with the top surface of the third spring cavity (50312), the position of an interface between the T-shaped oil duct (50313) and the third spring cavity (50312) is shielded by the piston (50343), the distance between the bottom of the interface between the T-shaped oil duct (50313) and the third spring cavity (50312) and the top surface of the third spring cavity (50312) is the same as the stroke of the die cutting disc (5034),

a positioning hole (503431) is arranged on the circumferential surface of the piston (50343), a through hole which is communicated with the third spring cavity (50312) is arranged on the first shell, an electromagnet (5033) is fixed outside the through hole, a telescopic rod of the electromagnet (5033) passes through the through hole to be contacted with the circumferential surface of the piston (50343),

when the piston (50343) moves to the uppermost part, the positioning hole (503431) is positioned at the uppermost part of the telescopic rod of the electromagnet (5033), the distance between the axis of the positioning hole (503431) and the axis of the telescopic rod of the electromagnet (5033) is the same as the stroke of the die-cutting disc (5034),

a pressing plate (504) is respectively arranged at the front end and the rear end of the die cutter (503) above the bottom plate (501),

a third slide bar (5041) is fixed above the central position of the pressing plate (504), a stand column (5021) is fixed at a position of the top plate (502) corresponding to the third slide bar (5041), a first spring cavity (5022) is arranged in the stand column (5021), the tail end of the third slide bar (5041) is penetrated into the first spring cavity (5022), a second spring seat (5043) is fixed on the top surface of the third slide bar (5041),

A third sliding rod (5041) positioned in the first spring cavity (5022) is sleeved with a third spring (5042),

a hydraulic oil main pipe (505) is arranged above the top plate (502), a pressing plate branch pipe (5051) and a die cutter branch pipe (5052) are respectively and communicated with the hydraulic oil main pipe (505), the length of the pressing plate branch pipe (5051) is shorter than that of the die cutter branch pipe (5052), the pressing plate branch pipe (5051) is closer to an inlet of the hydraulic oil main pipe (505) than that of the die cutter branch pipe (5052),

the pressing plate branch pipe (5051) is communicated with the top of the first spring cavity (5022), the die cutter branch pipe (5052) is communicated with the inlet of the Y-shaped oil pipe (5032),

a guide rod (5044) is arranged above two sides of the pressing plate (504), the top of the guide rod (5044) passes through the top plate (502),

the laser coding machines (7) with the same number as the die grooves (301) are arranged above the conveying mechanism (2) in a row, lenses of the laser coding machines (7) are arranged vertically downwards, the axes of the lenses and the axes of the die grooves (301) are positioned on the same vertical plane,

at least two guide wheels (11) which are rotationally connected with the bracket (1) are arranged above the conveying mechanism (2), the two guide wheels (11) are arranged in a staggered way from top to bottom, the guide wheel (11) positioned at the bottom point is arranged between the foaming material injection device (4) and the die cutting device (5), the guide wheel (11) positioned at the high point is higher than the foaming material injection device (4),

The electronic tag bearing belt (1101) is contacted with the guide wheel (11) at the low point and the guide wheel (11) at the high point after passing through the die cutting device (5).

2. The device for manufacturing an electronic label anti-counterfeiting gasket according to claim 1, wherein:

the conveying mechanism (2) comprises two annular rubber belts (201), the gasket mould (3) is arranged between the two rubber belts (201),

the front and rear ends of the inside of the two rubber belts (201) are respectively provided with a rotating shaft (202) in a penetrating way, the central shaft of the rotating shaft (202) is inserted into the inner wall of the bracket (1),

the central shaft of one rotating shaft (202) penetrates through the bracket (1) and is connected with the driving end of the driving device (203).

3. The device for manufacturing an electronic label anti-counterfeiting gasket according to claim 2, wherein:

a placing plate (303) is fixed on the end face of the gasket mould (3) facing the rubber belt (201), a first rotating rod (304) is fixed below the placing plate (303), the axis of the first rotating rod (304) is parallel to the axis of the rotating shaft (202),

the placing plate (303) is placed above the rubber belt (201), a trapezoid groove (2011) is formed in the position, below the placing plate (303), of the top surface of the rubber belt (201), the first rotating rod (304) is arranged inside the trapezoid groove (2011), and two ends of the first rotating rod (304) are inserted into the inner wall of the trapezoid groove (2011).

4. The apparatus for manufacturing an electronic label anti-counterfeiting gasket according to claim 3, wherein:

two ends of the die cutting device (5) are provided with a foaming material injection device (4), two groups of guide wheels (11) are arranged above the conveying mechanism (2), each group of guide wheels (11) comprises a low-level guide wheel (11) and a high-level guide wheel (11),

the two groups of guide wheels (11) are symmetrically arranged relative to the die cutting device (5), and the lower guide wheel (11) is positioned between the die cutting device (5) and the foaming material injection device (4).

5. The device for manufacturing an electronic label anti-counterfeiting gasket according to claim 4, wherein:

the foaming material injection device (4) comprises a main pipe (401), an electric control valve (402) and discharge pipes (403), wherein the electric control valve (402) is arranged at the inlet of the main pipe (401), a plurality of discharge pipes (403) are arranged below the main pipe (401) and are communicated with the main pipe (401),

a vibrating device (8) is arranged right below the foaming material injection device (4), the vibrating device (8) comprises a vibrator (801) and a mounting plate (805), the vibrator (801) is fixed above the mounting plate (805),

When the gasket mould (3) moves to the position right below the foaming material injection device (4), the vibrator (801) is contacted with the gasket mould (3),

a sensor bracket (404) is fixed on the main pipe (401), two groups of second pair of photoelectric sensors (15) are arranged on the sensor bracket (404) and the mounting plate (805), the distance between the two groups of second pair of photoelectric sensors (15) is the same as the width of the gasket mould (3),

the emitter and the receiver contained in each group of second correlation photoelectric sensors (15) are respectively and fixedly connected with the sensor bracket (404) and the mounting plate (805).

6. The device for manufacturing an electronic label anti-counterfeiting gasket according to claim 5, wherein:

the vibrator (801) below be equipped with sill bar (802), mounting panel (805) top is equipped with connecting rod (804), is connected through damping device (803) between sill bar (802) and connecting rod (804).

7. The device for manufacturing an electronic label anti-counterfeiting gasket according to claim 5, wherein:

an arc-shaped protective cover (12) is covered outside an arc-shaped area of the conveying mechanism (2) positioned at the front end of the electronic tag bearing belt (1101) in the moving direction, the radian of the arc-shaped protective cover (12) is 90-180 degrees, the end surface of the lower side of the arc-shaped protective cover (12) and the axis of a rotating shaft (202) wrapped by the arc-shaped protective cover are positioned on the same vertical plane,

The arc-shaped protective cover (12) is fixedly connected with the bracket (1),

the inside of the conveying mechanism (2) is provided with a striking device (13), the striking device (13) comprises a second rotating rod (1301), a cylinder (1303) and an arc plate (1304),

two ends of a second rotating rod (1301) are arranged in the inner wall of the bracket (1) in a penetrating way, one end of the second rotating rod (1301) is fixedly connected with an output shaft of a third motor (1302), a plurality of cylinders (1303) are mutually perpendicular to the second rotating rod (1301) and are fixedly connected,

the cambered surface of the arc plate (1304) faces away from the cylinder (1303), a fourth slide bar (13041) is fixed on the end surface of the arc plate (1304) corresponding to the cylinder (1303), the tail end of the fourth slide bar (13041) penetrates into a spring cavity in the cylinder (1303), a third spring seat (13042) is fixed at the tail end of the fourth slide bar (13041), a fourth spring (1305) is sleeved outside the fourth slide bar (13041) in the spring seat of the cylinder (1303),

when the fourth slide bar (13041) is in a vertical state, the distance between the axis of the fourth slide bar (13041) and the end surface of the bottom of the arc-shaped protective cover (12) is the same as the width of the gasket mould (3),

a sorting conveyor belt (9) is arranged below the striking device (13), the sorting conveyor belt (9) is positioned below the conveying mechanism (2), the sorting conveyor belt (9) and the conveying mechanism (2) are mutually vertically arranged,

An electronic tag reader (901) is fixed at the upper end of the sorting conveyor belt (9), a first pair of photoelectric sensors (904) are arranged under the electronic tag reader (901), the transmitters and the receivers of the first pair of photoelectric sensors (904) are respectively arranged at the two sides of the sorting conveyor belt (9),

an electric push rod (903) is fixed on the side surface of the sorting conveyor belt (9), the electric push rod (903) is positioned at the front end of the electronic tag reader (901), the distance between the electric push rod (903) and the electronic tag reader (901) is the same as the distance between two adjacent die cavities (301) on the gasket die (3),

the other side of the sorting conveyor belt (9) corresponding to the electric push rod (903) is fixedly provided with an inclined plate (902) which is arranged obliquely downwards, and the width of the inclined plate (902) is larger than the inner diameter of the die cavity (301).