CN109272858B - Drop with multilayer anti-counterfeiting technology and manufacturing method thereof - Google Patents

Abstract

The application provides a drop with multilayer anti-fake technology and a manufacturing method thereof, the drop has comprehensive anti-fake effect, specifically, a plurality of anti-fake technical layers for anti-fake are arranged on the drop, and a holographic anti-fake technical code layer which is thermoprinted by using a positioning holographic thermoprinting technology is particularly arranged, so that anti-fake identification and the drop are tightly combined together, the anti-fake identification and the drop are integrated, once the anti-fake identification is torn off, the drop is seriously damaged, and the problem that the anti-fake identification is invalid due to the fact that the anti-fake identification is attached to the drop is solved.

Description

Drop with multilayer anti-counterfeiting technology and manufacturing method thereof

Technical Field

The application belongs to the field of anti-counterfeiting, and particularly relates to a tag with a multilayer anti-counterfeiting technology and a manufacturing method thereof.

Background

The holographic thermoprinting technology is a novel anti-fake technology, which has been used widely at home and abroad, but only for a few years.

The anti-fake film produced by utilizing holographic technology is an anti-fake mark produced by utilizing laser color hologram plate making technology and accurate mold pressing technology. It is mainly used for various anti-counterfeit of ticket, credit card, passport, banknote, trademark and package.

At present, the application of the holographic thermoprinting anti-counterfeiting technology in the field of clothing labels mainly comprises two types: the first is to use the anti-fake mark and the clothing hangtag to hang on the description of the clothing separately; the second is to adhere the anti-counterfeiting mark to the garment tag. The first anti-counterfeiting mark application has the defect that the first anti-counterfeiting mark is easily replaced by a fake anti-counterfeiting mark, so that the anti-counterfeiting effect is lost; the second anti-counterfeiting mark is easy to be torn off by various methods because of being stuck on the tag, the anti-counterfeiting effect is poor, and the production cost of the tag is increased year by year along with the annual increase of labor cost.

Therefore, there is a need to develop a hangtag that has good security properties and is low in cost.

Disclosure of Invention

The application provides a drop with multilayer anti-fake technology and a manufacturing method thereof, the drop has comprehensive anti-fake effect, specifically, a plurality of anti-fake technical layers for anti-fake are arranged on the drop, and a holographic anti-fake technical code layer which is thermoprinted by using a positioning holographic thermoprinting technology is particularly arranged, so that anti-fake identification and the drop are tightly combined together, the anti-fake identification and the drop are integrated, once the anti-fake identification is torn off, the drop is seriously damaged, and the problem that the anti-fake identification is invalid due to the fact that the anti-fake identification is attached to the drop is solved.

The application provides a drop with anti-fake sign specifically including drop base member 1 with three-dimensional set up in the multilayer on the drop base member 1 is used for anti-fake technical layer, the multilayer is used for anti-fake technical layer specifically includes: an encrypted graphic layer 3 provided on the tag substrate 1; a fluorescent color-developing pattern layer 4 which is arranged on the tag substrate 1 and is printed by anti-counterfeiting ink; and a holographic anti-counterfeiting technical code layer 5 printed on the fluorescent color-development pattern layer 4.

The anti-counterfeiting paper 2 is arranged on the tag substrate 1, at least one anti-counterfeiting paper 2 is arranged, and a plurality of anti-counterfeiting papers 2 are separated; the anti-counterfeiting paper 2 is paper showing different colors from different angles; a preset pattern layer is fixedly arranged on the anti-counterfeiting paper 2, the preset pattern layer comprises a pattern patch and preset patterns arranged on the pattern patch, wherein the preset patterns comprise character patterns and pattern patterns;

the encryption graphic layer 3 is separated from any anti-counterfeiting paper 2;

randomly generating the position of the anti-counterfeiting paper 2 on each tag substrate 1;

wherein, the holographic anti-counterfeiting technical code layer 5 is printed by a method comprising the following steps:

step 1-1, respectively engraving a hollowed-out two-dimensional code, a hollowed-out digital code and a laser holographic trademark on each transfer printing area of a holographic foil roll by using laser, wherein the hollowed-out two-dimensional code and the hollowed-out digital code on each transfer printing area are randomly generated and are different, the laser holographic trademarks are completely the same, and the hollowed-out two-dimensional code on the same transfer printing area corresponds to the hollowed-out digital code;

step 1-2, placing the holographic foil roll in an unreeling device of a thermoprinting machine, placing a pre-thermoprinted hangtag substrate in a paper feeding table of the thermoprinting machine, and switching on a power supply of the thermoprinting machine to preheat a honeycomb plate;

step 1-3, arranging transparent double faced adhesive tape at the position of the holographic anti-counterfeiting technical code layer 5 on the tag substrate in a pre-hot stamping mode;

step 1-4, simultaneously pulling the tag substrate 1 and the holographic foil coil to enable the hollowed-out two-dimensional code to be covered on the fluorescent color-developing pattern layer 4;

and step 1-5, applying pressure to the tag substrate 1. In one possible way, the shape of the fluorescent chromogenic graphic layer 4 is the same as the shape of the trademark of the product;

in one implementation manner, the holographic anti-counterfeiting technical code layer 5 includes a hollowed-out two-dimensional code area 51, a hollowed-out digital code area 52 and a laser holographic trademark area 53 which are separated, wherein the hollowed-out two-dimensional code area 51 covers the upper layer of the fluorescent color-developing pattern layer 4.

Optionally, in step 1-2, the preheating temperature is 80-120 ℃.

In one implementation manner, the encryption graphic layer 3 includes a data information number sub-layer 31, a PKI key number sub-layer 32, a denoising anti-counterfeiting number sub-layer 33, and a physical carrier copy verification model sub-layer 34, which are sequentially stacked, wherein the data information number sub-layer 31 is attached to the tag substrate 1.

In one realisable way, the profile of the encryption graphic layer 3 is identical to the profile of the product brand.

The application provides a drop with synthesize anti-fake technique is fixed the setting on the drop base member with multilayer anti-fake technique layer, adopts holographic thermoprint technique to make fretwork two-dimensional code layer and fluorescent color-development figure layer overlap very much, strengthens anti-fake effect to unable replication, moreover, anti-fake identification code layer uses holographic thermoprint technique to paste and covers on the drop base member, has both removed the operation that the manual work pasted, also prevents that anti-fake label from being shifted, has increased and has made fake cost and degree of difficulty.

The application also provides a method for printing the hangtag, which comprises the following steps:

step 1, printing a fluorescent color-developing pattern layer 4 on the tag substrate 1 by using anti-counterfeiting ink;

step 2, printing a holographic anti-counterfeiting technical code layer 5 on the tag substrate 1, wherein a hollowed-out two-dimensional code area 51 of the holographic anti-counterfeiting technical code layer 5 is covered on the fluorescent color-development pattern layer 4;

the step 2 specifically includes:

step 1-1, carving a hollowed-out two-dimensional code, a hollowed-out digital code and a laser holographic trademark on each transfer printing area of a holographic foil roll by using laser, wherein the hollowed-out two-dimensional code and the hollowed-out digital code on each transfer printing area are randomly generated and are different, the laser holographic trademarks are completely the same, and the hollowed-out two-dimensional code on the same transfer printing area corresponds to the hollowed-out digital code;

step 1-2, placing the holographic foil roll in an unreeling device of a thermoprinting machine, placing a pre-thermoprinted hangtag substrate in a paper feeding table of the thermoprinting machine, and switching on a power supply of the thermoprinting machine to preheat a honeycomb plate;

step 1-3, arranging transparent double faced adhesive tape at the position of the holographic anti-counterfeiting technical code layer 5 on the tag substrate in a pre-hot stamping mode;

step 1-4, simultaneously pulling the tag substrate 1 and the holographic foil coil to enable the hollowed-out two-dimensional code to be covered on the fluorescent color-developing pattern layer 4;

step 1-5, applying pressure to the tag substrate 1;

step 3, printing an encryption graphic layer 3 on the tag substrate 1, wherein the encryption graphic layer 3 is separated from the anti-counterfeiting technical code layer 5;

and 4, arranging anti-counterfeiting paper 2 on the tag substrate 1, wherein at least one anti-counterfeiting paper 2 is separated from a plurality of anti-counterfeiting papers 2, a preset graphic layer is fixedly arranged on the anti-counterfeiting paper 2, the encrypted graphic layer 3 is separated from any anti-counterfeiting paper 2, and the positions of the anti-counterfeiting papers 2 on each tag substrate 1 are randomly generated.

The method provided by the application can print various anti-counterfeiting technical layers on the tag substrate at one time, so that the anti-counterfeiting mark and the tag are integrally arranged, thereby increasing the counterfeiting difficulty and the anti-counterfeiting strength.

Drawings

FIG. 1 is a schematic diagram of a front view of a hangtag with anti-counterfeiting mark;

FIG. 2 is a schematic bottom view of the swing ticket of FIG. 1;

FIG. 3 is a schematic right-hand structural view of the swing ticket of FIG. 1;

fig. 4 is an exploded structural view of the encryption graphic layer.

Description of the reference numerals

The anti-fake label comprises a 1-label substrate, 2-anti-fake paper, a 3-encryption graphic layer, a 31-data information number sub-layer, a 32-PKI key number sub-layer, a 33-denoising anti-fake number sub-layer, a 34-physical carrier copy verification model sub-layer, a 4-fluorescent chromogenic graphic layer, a 5-holographic anti-fake technology code layer, a 51-hollowed two-dimensional code area, a 52-hollowed digital code area and a 53-laser holographic trademark area.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples do not represent all implementations consistent with the invention. Rather, they are merely examples of apparatus and methods consistent with aspects of the invention as detailed in the accompanying claims.

Fig. 1 is a schematic front view structure of the tag with anti-counterfeiting mark, fig. 2 is a schematic bottom view structure of the tag shown in fig. 1, fig. 3 is a schematic right view structure of the tag shown in fig. 1, and as shown in fig. 1 to fig. 3, a tag substrate 1 and a plurality of anti-counterfeiting technical layers for anti-counterfeiting which are three-dimensionally arranged on the tag substrate 1, wherein the plurality of anti-counterfeiting technical layers for anti-counterfeiting specifically include: the encrypted pattern layer 3, the fluorescent color development pattern layer 4 and the holographic anti-counterfeiting technical code layer 5 are arranged on the tag substrate 1.

In this embodiment, the swing ticket base 1 may be a paper swing ticket, such as a particular hard card.

In one possible way, one side of the tag body 1 is printed with a trademark of the enterprise, and the other side is printed with a description of "genuine assurance". In this embodiment, different anti-counterfeiting technical layers can be loaded on the side printed with the "genuine product guarantee" so that the tag has unique anti-counterfeiting characteristics.

In this embodiment, an anti-counterfeiting paper 2 may also be disposed on the tag substrate 1, and at least one anti-counterfeiting paper 2 is disposed on the tag substrate 1, where the anti-counterfeiting papers 2 are separated.

In this embodiment, the security paper 2 is paper capable of exhibiting different colors or color intensities from different angles, for example: the surface of the anti-counterfeiting paper has blue pearly luster, and the color intensity of the anti-counterfeiting sticker is changed by changing the angle under sunlight.

In the embodiment, the anti-counterfeiting paper with light blue and pink is selected, so that a user can conveniently observe color change in sunlight.

In this embodiment, the anti-counterfeit paper 2 may have any shape, and may be regular hexagon, circle, triangle, etc.

In this embodiment, the anti-counterfeiting paper 2 is randomly arranged on the tag substrate 1, so that the probability that the positions and colors of all the anti-counterfeiting papers on any two tags are identical is extremely low, and the anti-counterfeiting function is that the tags cannot be imitated in any later mode, thereby preventing the tags from being counterfeited. Moreover, the anti-counterfeiting characteristics generated by the anti-counterfeiting paper are simple to identify by naked eyes of users, can be detected by instruments, and have convenience. The applicant has found that the security paper 2 carries security technology organically combined with paper fibres; the anti-counterfeiting function cannot be imitated in any later mode, and the monopolization of anti-counterfeiting technology, the anti-counterfeiting identification characteristics, the quantity, the imitation difficulty, the imitation cost, the technical level, the safety period, the stability period and the like completely accord with the national class A force; the patches are randomly distributed in the paper, and have the effects which cannot be realized by the security threads, the watermarks and the color fibers

The anti-counterfeiting paper 2 is fixedly provided with a preset pattern layer, the preset pattern layer comprises a pattern patch and preset patterns arranged on the pattern patch, and the preset patterns comprise character patterns and pattern patterns. For example, a graphic patch is attached to the surface of the security paper 2, and the letter "Panpass" is printed on the graphic patch, wherein the letter "Panpass" is an english abbreviation of a trademark of a product.

In this embodiment, the encryption graphic layer 3 is a graphic layer printed with micro-encryption graphics, where the micro-encryption graphics are two-dimensional security images formed by combining digital cryptography with typical physical carrier features, and jointly encrypting and converting digitalized information such as characters and photos and security function information for anti-counterfeiting verification through a unique coding mode, and the encryption graphic layer 3 is printed on the tag substrate 1. In this embodiment, in the micro-encryption graphics layer 3, the enterprise LOGO is encrypted by taking the megatrademark as an example, so that the function of anti-counterfeiting verification is well achieved.

Fig. 4 is an exploded structure diagram of the encryption graphic layer 3, as shown in fig. 4, the encryption graphic layer 3 includes a data information number sub-layer 31, a PKI key number sub-layer 32, a denoising anti-counterfeiting number sub-layer 33, and a physical carrier copy verification model sub-layer 34, which are sequentially stacked, wherein the data information number sub-layer 31 is attached to the tag substrate 1.

In one possible way, the encryption graphic layer 3 is separate from any of the security papers 2, i.e., the encryption graphic layer 3 does not overlap any of the security papers 2.

Further, the shape of the encryption graphic layer 3 is a graphic based on a trademark outline, for example, the trademark of the commodity is a trademark pattern of Beijing megaletter, and the shape of the encryption graphic layer 3 may be a shape conforming to the trademark.

In this embodiment, the fluorescent color-developing pattern layer 4 is printed on the tag substrate 1, and the fluorescent color-developing pattern layer 4 is printed with anti-counterfeit ink, so that the fluorescent color-developing pattern is not displayed in sunlight or ordinary light, but can be displayed only under fluorescent irradiation conditions.

In this embodiment, the holographic anti-counterfeiting technical code layer 5 is printed on the fluorescent color-developing pattern layer 4 by using a positioning holographic thermoprinting technology.

In one implementation, the holographic anti-counterfeiting technical code layer 5 is printed above the fluorescent color-development pattern layer 4 by adopting a hot stamping method. In the thermoprinting method, a two-dimensional code carving technology is used, for example, in OVDOptical Variable Device, a laser carving mode is used on a transfer layer of an optically variable image positioning thermoprinting foil, a laser carving hollowed-out two-dimensional code is positioned in a hollowed-out two-dimensional code area 51, a laser carving digital code is positioned in a hollowed-out digital code area 52, and then an OVD-two-dimensional code mark is transferred to the tag substrate in a positioning hot-pressing thermoprinting mode, so that a novel anti-counterfeiting mark is formed by combining the OVD positioning thermoprinting technology with the two-dimensional code technology, the anti-counterfeiting mark has the advantages of the OVD and the two-dimensional code, the defects of the two-dimensional code are avoided, and a brand-new multifunctional composite anti-counterfeiting mark product with the OVD optical anti-counterfeiting characteristic and the two-dimensional code characteristic is formed.

In one implementation, the holographic anti-counterfeiting technical code layer 5 is printed by using a thermoprinting machine, wherein the thermoprinting machine comprises an unreeling device and a paper feeding table, the unreeling device is used for placing a holographic foil roll, and the holographic foil roll can be continuously pulled out of the unreeling device along with the holographic foil roll and rotates around a central shaft of the holographic foil roll; the paper feeding table is used for containing a tag substrate 1 to be printed, and is connected with a paper outlet of the unreeling device, so that the holographic printing foil roll pulled out of the unreeling device is in pressure contact with the tag substrate 1 to be printed, and information on the holographic printing foil roll is completely transferred onto the tag substrate 1.

The holographic anti-counterfeiting technical code layer 5 is printed by a method comprising the following steps:

step 1-1, respectively engraving a hollowed-out two-dimensional code, a hollowed-out digital code and a laser holographic trademark on each transfer printing area of the holographic foil roll by using laser, wherein the hollowed-out two-dimensional codes on each transfer printing area are randomly generated and different, the hollowed-out digital codes are also randomly generated and different, the laser holographic trademarks are completely the same, and the hollowed-out two-dimensional codes on the same transfer printing area correspond to the hollowed-out digital codes.

Step 1-2, placing the holographic foil roll in an unreeling device of a thermoprinting machine, placing a pre-thermoprinted tag substrate in a paper feeding table of the thermoprinting machine, switching on a power supply of the thermoprinting machine to preheat a honeycomb plate, wherein the final temperature of the honeycomb plate can enable information on the holographic foil roll to be transferred onto the tag substrate, and can prevent the tag from being deformed such as shrinkage, and the final temperature of preheating can be 80-120 ℃.

And 1-3, pre-stamping transparent double-sided adhesive tape at the position of the holographic anti-counterfeiting technical code layer 5 on the tag substrate, so as to prevent the opaque double-sided adhesive tape from shielding the fluorescent color-development pattern layer 4, and the manufactured anti-counterfeiting tag can observe the pattern displayed by the fluorescent color-development pattern layer 4 through the gap of the hollowed-out two-dimensional code.

And step 1-4, simultaneously pulling the tag substrate 1 and the holographic foil coil, so that the hollowed-out two-dimensional code area 51 is covered on the fluorescent color-developing pattern layer 4.

And step 1-5, applying pressure to the tag substrate 1 so that the film on the holographic foil roll is tightly adhered to the tag substrate 1.

The high-quality holographic foil roll is very thin, and the thickness of the holographic foil roll just can meet the basic requirement of mould pressing on the thickness, but the holographic foil roll has quite complex structure and generally consists of a carrier film, a stripping layer, a transfer printing layer, an aluminized layer and an adhesive layer.

The fluorescent color development pattern layer 4 can penetrate through gaps of the anti-counterfeiting mark in the holographic anti-counterfeiting technology code layer 5, and partial fluorescent color development patterns can be observed under fluorescent conditions.

The present application also provides a method of printing the aforementioned hangtag, the method comprising the steps of:

step 1, printing a fluorescent color-developing pattern layer 4 on the tag substrate 1 by using anti-counterfeiting ink;

step 2, printing a holographic anti-counterfeiting technical code layer 5 on the tag substrate 1, covering a hollowed-out two-dimensional code area 51 of the holographic anti-counterfeiting technical code layer 5 on the fluorescent color-developing pattern layer 4,

and 3, printing an encryption graphic layer 3 on the tag substrate 1.

And 4, arranging anti-counterfeiting paper 2 on the tag substrate 1, wherein at least one anti-counterfeiting paper 2 is separated from a plurality of anti-counterfeiting papers 2, a preset graphic layer is fixedly arranged on the anti-counterfeiting paper 2, the encrypted graphic layer 3 is separated from any anti-counterfeiting paper 2, and the positions of the anti-counterfeiting papers 2 on each tag substrate 1 are randomly generated.

The specific method in step 3 refers to the printing method of the holographic anti-counterfeit technical code layer 5, and will not be described herein.

In this embodiment, after step 2, before step 3, the following step 2 may be further included: and sticking the anti-counterfeiting paper 2 on the tag substrate 1, wherein the anti-counterfeiting paper 2 is separated from the fluorescent chromogenic pattern layer 4.

In this embodiment, if the anti-counterfeiting paper 2 is attached to the tag substrate 1 through the step 2, in the step 3, the encryption graphic layer 3 is separated from the anti-counterfeiting paper 2 and the holographic anti-counterfeiting technical code layer 5.

The foregoing detailed description has been provided for the purposes of illustration in connection with specific embodiments and exemplary examples, but such description is not to be construed as limiting the application. Those skilled in the art will appreciate that various equivalent substitutions, modifications and improvements may be made to the technical solution of the present application and its embodiments without departing from the spirit and scope of the present application, and these all fall within the scope of the present application. The scope of the application is defined by the appended claims.

Claims (7)

1. The utility model provides a drop with multilayer anti-fake technique, its characterized in that, the drop include drop base member (1) and set up in the multilayer on drop base member (1) is used for anti-fake technique layer, the multilayer is used for anti-fake technique layer specifically includes:

an encrypted graphic layer (3) arranged on the tag substrate (1);

a fluorescent color-developing pattern layer (4) which is arranged on the tag substrate (1) and is printed by anti-counterfeiting ink;

a holographic anti-counterfeiting technical code layer (5) which is thermoprinted on the fluorescent color-development graphic layer (4) by using a positioning holographic thermoprinting technology;

the anti-counterfeiting label comprises a label substrate (1), wherein anti-counterfeiting paper (2) is arranged on the label substrate (1), at least one anti-counterfeiting paper (2) is arranged, and a plurality of anti-counterfeiting papers (2) are separated, wherein the anti-counterfeiting papers (2) are papers showing different colors from different angles; and/or

A preset pattern layer is fixedly arranged on the anti-counterfeiting paper (2), the preset pattern layer comprises a pattern patch and a preset pattern arranged on the pattern patch, and the preset pattern comprises a character pattern and a pattern; and/or

The encryption graphic layer (3) is separated from any anti-counterfeiting paper (2);

the positions of the anti-counterfeiting papers (2) on each tag substrate (1) are randomly generated;

wherein, the holographic anti-counterfeiting technical code layer (5) is printed by a method comprising the following steps:

step 1-1, respectively engraving a hollowed-out two-dimensional code, a hollowed-out digital code and a laser holographic trademark on each transfer printing area of a holographic foil roll by using laser, wherein the hollowed-out two-dimensional code and the hollowed-out digital code on each transfer printing area are randomly generated and are different, the laser holographic trademarks are completely the same, and the hollowed-out two-dimensional code on the same transfer printing area corresponds to the hollowed-out digital code;

step 1-2, placing the holographic foil roll in an unreeling device of a thermoprinting machine, placing a pre-thermoprinted hangtag substrate in a paper feeding table of the thermoprinting machine, and switching on a power supply of the thermoprinting machine to preheat a honeycomb plate;

step 1-3, arranging transparent double-sided adhesive tape at the position of the holographic anti-counterfeiting technical code layer (5) on the tag substrate in a pre-hot stamping way;

step 1-4, simultaneously pulling the tag substrate (1) and the holographic foil printing roll to enable the hollowed-out two-dimensional code to be covered on the fluorescent color development pattern layer (4);

and step 1-5, applying pressure to the tag substrate (1).

2. A hangtag according to claim 1, characterised in that said fluorescent coloured graphic layer (4) has the same shape as the product brand.

3. The hangtag according to claim 1, wherein the holographic anti-counterfeiting technical code layer (5) comprises a hollowed-out two-dimensional code area (51), a hollowed-out digital code area (52) and a laser holographic trademark area (53) which are separated, wherein the hollowed-out two-dimensional code area (51) is covered on the upper layer of the fluorescent color-developing graphic layer (4).

4. A hangtag according to claim 1, wherein in step 1-2 the preheating is at a temperature of 80 ℃ to 120 ℃.

5. The tag according to claim 1, characterized in that the encryption graphic layer (3) comprises a data information number sub-layer (31), a PKI key number sub-layer (32), a denoising anti-counterfeiting number sub-layer (33) and a physical carrier replication verification model sub-layer (34) which are laminated in sequence, wherein the data information number sub-layer (31) is attached to the tag substrate (1).

6. A hangtag according to claim 1, characterised in that said layer (3) has the same outline as the product brand.

7. A method of making a swing ticket according to any one of claims 1 to 6, the method comprising the steps of:

step 1, printing a fluorescent color-developing pattern layer (4) on the tag substrate (1) by using anti-counterfeiting ink;

step 2, printing a holographic anti-counterfeiting technical code layer (5) on the tag substrate (1), wherein a hollowed-out two-dimensional code area (51) of the holographic anti-counterfeiting technical code layer (5) is covered on the fluorescent color development pattern layer (4);

the step 2 specifically includes:

step 1-1, carving a hollowed-out two-dimensional code, a hollowed-out digital code and a laser holographic trademark on each transfer printing area of a holographic foil roll by using laser, wherein the hollowed-out two-dimensional code and the hollowed-out digital code on each transfer printing area are randomly generated and are different, the laser holographic trademarks are completely the same, and the hollowed-out two-dimensional code on the same transfer printing area corresponds to the hollowed-out digital code;

step 1-2, placing the holographic foil roll in an unreeling device of a thermoprinting machine, placing a pre-thermoprinted hangtag substrate in a paper feeding table of the thermoprinting machine, and switching on a power supply of the thermoprinting machine to preheat a honeycomb plate;

step 1-3, arranging transparent double-sided adhesive tape at the position of the holographic anti-counterfeiting technical code layer (5) on the tag substrate in a pre-hot stamping way;

step 1-4, simultaneously pulling the tag substrate (1) and the holographic foil printing roll to enable the hollowed-out two-dimensional code to be covered on the fluorescent color development pattern layer (4);

step 1-5, applying pressure to the tag matrix (1);

printing an encryption graphic layer (3) on the tag substrate (1), wherein the encryption graphic layer (3) is separated from the holographic anti-counterfeiting technical code layer (5);

and 4, arranging anti-counterfeiting paper (2) on the tag substrate (1), wherein at least one anti-counterfeiting paper (2) is arranged, a plurality of anti-counterfeiting papers (2) are separated, a preset pattern layer is fixedly arranged on the anti-counterfeiting paper (2), the encryption pattern layer (3) is separated from any anti-counterfeiting paper (2) in a homogeneous phase, and the positions of the anti-counterfeiting papers (2) on each tag substrate (1) are randomly generated.