CN211518697U - Laser transfer anti-counterfeiting film, laser transfer anti-counterfeiting paper and production equipment - Google Patents

Abstract

The utility model discloses a radium-shine transfer anti-fake membrane, radium-shine transfer anti-fake paper and production facility, wherein radium-shine transfer anti-fake membrane, the base film that can peel including range upon range of setting in proper order, local from type information layer, local aluminium lamination, overlay type are from type information layer and zinc sulfide layer, the local shape from type information layer and local aluminium lamination is the same, overlay type is in from the type information layer cover on the base film that local aluminium lamination and adjacent local aluminium lamination fretwork part expose. Radium-shine transfer antifalsification paper is including stacking gradually paper, glue film, zinc sulfide layer, the cover type that sets up from type information layer, local aluminium lamination and local type information layer, the local shape from type information layer and local aluminium lamination is the same, the cover type is in from type information layer cover local aluminium lamination and adjacent local aluminium lamination fretwork part make radium-shine transfer antifalsification paper have higher antifalsification ability.

Description

Laser transfer anti-counterfeiting film, laser transfer anti-counterfeiting paper and production equipment

Technical Field

The utility model relates to a radium-shine transfer anti-counterfeit paper technical field, in particular to radium-shine transfer anti-counterfeit film, radium-shine transfer anti-counterfeit paper and production facility.

Background

Vacuum aluminized paper began to enter people's lives since the 80 s. The vacuum aluminum-plated paper has the same metal texture as the aluminum foil composite paper, is superior to the aluminum foil composite paper in cost and environmental protection, and is called as a novel green packaging material in the packaging industry. Along with the continuous improvement of the life of people, the exquisite appearance and the anti-counterfeiting technology of product packaging are also continuously improved, the transparent colorful spot color printing ink printed on the aluminized paper can transmit noble and gorgeous metal luster, and the aluminum-plated paper is widely applied to outer packaging of cigarettes, wine, food, medicines, gift boxes and the like in daily life, is exquisite and gorgeous, and improves the attachment value of products. The laser processing is easy to carry out on the aluminized paper, the pattern and the character information are loaded in a mould pressing laser mode, and the laser aluminized paper has good anti-counterfeiting performance due to the complex production process, high technological content and large equipment investment.

In order to ensure that the outer package of the product has higher anti-counterfeiting performance, the local laser aluminized paper is produced, and from the aspect of commercial safety, the packaging material has extremely strong anti-counterfeiting performance, is favorable for improving the grade and the added value of the product, and has higher product competitiveness.

Common local laser paper in the current market is usuallyThe effect of local aluminizing of paper is achieved by adopting various aluminum washing processes, and from the principle, the corrosion reaction equation of aluminum is as follows: 2AL +2NaOH +2H₂O＝2NaAlO₂+3H₂. The disadvantages are that: 1. the adhesive force of the aluminum layer ink after the aluminum washing process is poor. 2. The aluminum washing takes long time, the energy consumption is high, the chemical stability is poor, and the positioning is difficult. 3. The aluminum washing process adopts a chemical reaction mode, and hydrogen is produced in the process, belongs to a class A hazardous gas and is easy to explode when exposed to open fire. 4. The soaked aluminum washing chemical reagent contains toxic chemical solvents, cross contamination is easy to generate in the water washing process, the aluminum washing chemical reagent is inconvenient to use on food packaging, a large amount of waste water is generated during aluminum washing, and the waste water treatment cost is high. 5. The sodium metaaluminate which is the product of the aluminum washing process is very easy to dissolve in water, the water solution of the sodium metaaluminate is strong alkaline, the sodium metaaluminate has strong corrosivity and high treatment cost, soil is easy to pollute, and the sodium metaaluminate has toxic hazard to crops in the soil.

Thus, the prior art has yet to be improved and enhanced.

SUMMERY OF THE UTILITY MODEL

In view of the defects of the prior art, the utility model aims to provide a radium-shine transfer anti-counterfeiting film, radium-shine transfer anti-counterfeiting paper and production facility.

For solving the technical problem, the utility model discloses following technical scheme has been taken:

the utility model provides a radium-shine transfer anti-counterfeiting membrane, is including the base film that stacks gradually the strippable of setting, local from type information layer, local aluminium lamination, overlay type from type information layer and zinc sulfide layer, the local shape from type information layer and local aluminium lamination is the same, overlay type is in from the type information layer cover on the base film that local aluminium lamination and adjacent local aluminium lamination fretwork part exposed.

In the laser transfer anti-counterfeiting film, the thickness of the local release information layer is 30-70 nanometers, and the thickness of the local aluminum layer is 50-90 nanometers.

In the laser transfer anti-counterfeiting film, the thickness of the thickest part of the covering type release information layer is 90-250 nanometers, and the thickness of the zinc sulfide layer is 40-80 nanometers.

The utility model provides a radium-shine transfer anti-counterfeit paper, is including stacking gradually paper, glue film, zinc sulfide layer, the overlay type that sets up from type information layer, local aluminium lamination and local type information layer, the local shape from type information layer and local aluminium lamination is the same, the overlay type is in from type information layer local aluminium lamination and adjacent local aluminium lamination fretwork part.

In the laser transfer anti-counterfeiting paper, the thickness of the local release information layer is 30-70 nanometers, and the thickness of the local aluminum layer is 50-90 nanometers.

In the laser transfer anti-counterfeiting paper, the thickness of the thickest part of the covering type release information layer is 90-250 nanometers, and the thickness of the zinc sulfide layer is 40-80 nanometers.

The utility model provides a production facility for making radium-shine transfer anti-fake membrane, radium-shine transfer anti-fake paper, is used for making the local fretwork device of the local fretwork of stripping film on the complex film, is used for preparing first coating unit, radium-shine moulding press, vacuum aluminizing device, zinc sulfide coating by vaporization device and coiling mechanism from type coating and second including setting gradually.

A production facility for making radium-shine anti-fake membrane, radium-shine anti-fake paper that shifts, unwinding device includes first unwinding roller, winding device includes first wind-up roll, local fretwork device is located between first unwinding roller and the first wind-up roll, including cabin, radio frequency laser ware, fan and cooling platform, the radio frequency laser ware set up in the cabin, the fan sets up in one side of radio frequency laser ware, the cooling platform sets up with the radio frequency laser ware relatively to have the clearance that supplies the complex film to pass through with the radio frequency laser ware.

A production facility for making radium-shine transfer anti-fake membrane, radium-shine transfer anti-fake paper, be provided with gas detector in the work cabin, the exhaust outlet department of work cabin has set gradually filter and air exhauster, gas detector is connected with filter and air exhauster electricity.

A production facility for making radium-shine transfer anti-counterfeiting membrane, radium-shine transfer anti-counterfeiting paper in, unwinding device still includes the second and unreels the roller, coiling mechanism still includes the second wind-up roll, coating device is located the second and unreels one side of roller and second wind-up roll, and it includes coating cistern, ceramic reticulation roller, impression rubber roll, partly in the coating liquid of coating cistern is located to ceramic reticulation roller, the impression rubber roll sets up in one side of ceramic reticulation roller, and rolls with ceramic reticulation roller and touch and press, ceramic reticulation roller and impression rubber roll are all counter-clockwise turning, the first type coating or second of coating from type coating on the complex film to by the rolling of second wind-up roll.

Compared with the prior art, the utility model provides a radium-shine transfer anti-counterfeiting film, radium-shine transfer anti-counterfeiting paper and production facility, wherein radium-shine transfer anti-counterfeiting paper is including stacking gradually paper, glue film, zinc sulfide layer, overlay type from type information layer, local aluminium lamination and local release type information layer, the local shape from type information layer and local aluminium lamination is the same, overlay type is covered from type information layer local aluminium lamination and adjacent local aluminium lamination fretwork part, the utility model discloses a mode of local radium-shine fretwork sets up the local radium-shine mould pressing pattern of type information layer demonstration on the aluminium lamination, and the fretwork part sets up overlay type from type information layer, and the below makes overlay type show radium-shine mould pressing pattern from type information layer through zinc sulfide layer, makes radium-shine transfer anti-counterfeiting paper have higher antifalsification can, is favorable to promoting the quality of packing.

Drawings

Fig. 1 is the structure diagram of the laser transfer anti-counterfeiting film provided by the utility model.

Fig. 2 is the schematic structural diagram of the laser transfer anti-counterfeiting film before peeling the peeling film.

Fig. 3 is a schematic view of the structure of the laser transfer anti-counterfeiting film after peeling the peeling film.

Fig. 4 is the structure diagram of the laser transfer anti-counterfeit paper provided by the utility model.

Fig. 5 is the utility model provides a schematic diagram of the structure of unwinding device, local fretwork device and the coiling mechanism of the equipment of radium-shine transfer anti-counterfeiting membrane of preparation.

Fig. 6 is the utility model provides a schematic diagram of the structure of unwinding device, coating unit and coiling mechanism of equipment of radium-shine transfer anti-counterfeiting membrane of preparation.

Fig. 7 is a flow chart of the preparation process of the laser transfer anti-counterfeit film paper provided by the utility model.

Fig. 8 is a schematic diagram when the peeling film of the laser transfer anti-counterfeiting film is hollowed out.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It will be understood that when an element is referred to as being "on," "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present.

It should be noted that the terms of orientation such as left, right, up and down in the embodiments of the present invention are only relative to each other or are referred to the normal use state of the product, and should not be considered as limiting.

Based on the problem that present radium-shine transfer anti-counterfeiting membrane exists of aluminizing, the embodiment of the utility model provides a radium-shine transfer anti-counterfeiting membrane 10 (as shown in fig. 1 and fig. 2), it is including the complex film 11 that stacks gradually the strippable of setting, local from type information layer 12, local aluminium lamination 13, overlay type from type information layer 14 and zinc sulfide layer 15, the local shape from type information layer 12 and local aluminium lamination 13 is the same, overlay type covers from type information layer 14 on the base film 112 of the complex film 11 that local aluminium lamination 13 and adjacent local aluminium lamination 13 fretwork part exposed.

The utility model discloses when using, only need make it compound with paper 21 at 15 coating glue on zinc sulfide layer, peel off the base film again, form radium-shine transfer anti-counterfeit paper 20 (as shown in figure 4), can directly be used for product packaging. The utility model discloses a mode of local radium-shine fretwork sets up the local radium-shine mould pressing pattern of type information layer 12 demonstration on the aluminium lamination, and the fretwork part sets up overlay type from type information layer 14, and the below makes overlay type from type information layer 14 demonstration radium-shine mould pressing pattern through zinc sulfide layer 15, makes radium-shine transfer anti-counterfeit paper 20 have higher antifalsification ability, is favorable to promoting the quality of packing.

In this embodiment, the base film 112 is a PE (Polyethylene) film, and is formed by first compounding a release film (OPP o-phenylphenol, i.e., OPP film) with the base film, and then hollowing out the release film 111 by a CO2 radio frequency laser 42 (as shown in fig. 8), so as to form shapes of the local release information layer 12 and the local aluminum layer 13 (as shown in fig. 2). After vacuum aluminum plating, the release film 111 is peeled off to form the partial release information layer 12 and the partial aluminum layer 13 (shown in fig. 3). Wherein, the thickness of the base film 112 is 10 μm to 20 μm, and the thickness of the peeling film 111 is 8 μm to 12 μm.

The thickness of the local release information layer 12 is 30-70 nanometers, the thickness of the local aluminum layer 13 is 50-90 nanometers, the thickness of the thickest part of the covering type release information layer 14 is 90-250 nanometers, and the thickness of the zinc sulfide layer 15 is 40-80 nanometers.

In a preferred embodiment, the thickness of the local aluminum layer 13 is 55-65nm, and the thickness of the zinc sulfide layer 15 is 55-70nm, so that the laser transfer anti-counterfeiting film 10 has good overall flexibility and strong metal feeling, and has better anti-counterfeiting performance, thereby facilitating the improvement of the packaging quality.

Based on foretell radium-shine transfer anti-counterfeiting film 10, the embodiment of the utility model provides a radium-shine transfer anti-counterfeiting paper 20 that still provides (as shown in fig. 4), it is including paper 21, glue film 22, zinc sulfide layer 15, the overlay type that stacks gradually the setting from type information layer 14, local aluminium lamination 13 and local type information layer 12, the local type is the same from type information layer 12 and local aluminium lamination 13's shape, the overlay type covers from type information layer 14 local aluminium lamination 13 and adjacent local aluminium lamination 13 fretwork part, directly with radium-shine transfer anti-counterfeiting film 10 complex on corresponding wrapping paper, saved follow-up packing and needed compound process, improved work efficiency. Meanwhile, the embodiment also adopts the mode of local laser hollowing, the aluminum layer is provided with a local release information layer 12 for displaying laser mould pressing patterns, the hollow part is provided with an overlay type release information layer 14, the lower part enables the overlay type release information layer 14 to display laser mould pressing patterns through a zinc sulfide layer 15, and the laser transfer anti-counterfeiting paper 20 has higher anti-counterfeiting performance and is beneficial to improving the quality of packaging.

Similarly, the base film 112 is a PE (Polyethylene) film, and is formed by first compounding a release film (OPP o-phenylphenol, i.e., OPP film) with the base film, and then hollowing out the release film by the CO2 rf laser 42, so as to form the shapes of the local release information layer 12 and the local aluminum layer 13. After vacuum aluminum plating, the release film is peeled off to form the partial release information layer 12 and the partial aluminum layer 13. Wherein, the thickness of the base film 112 is 10 μm to 20 μm, and the thickness of the peeling film 111 is 8 μm to 12 μm.

The thickness of the local release information layer 12 is 30-70 nanometers, the thickness of the local aluminum layer 13 is 50-90 nanometers, the thickness of the thickest part of the covering type release information layer 14 is 90-250 nanometers, and the thickness of the zinc sulfide layer 15 is 40-80 nanometers.

In a preferred embodiment, the thickness of the local aluminum layer 13 is 55-65nm, and the thickness of the zinc sulfide layer 15 is 55-70nm, so that the laser transfer anti-counterfeiting paper 20 has good overall flexibility and strong metal feeling, and has better anti-counterfeiting performance, which is beneficial to improving the quality of packaging.

Based on the above-mentioned laser transfer anti-counterfeit film 10 and laser transfer anti-counterfeit paper 20, the utility model also provides a production facility for manufacturing the laser transfer anti-counterfeit film 10 and laser transfer anti-counterfeit paper 20, please refer to fig. 5 together, which includes an unreeling device (not shown in the figure) for providing the composite film 11, a local hollowing device 4 for locally hollowing out the stripping film 112 on the composite film 11, a coating device 5 for preparing the first release coating and the second release coating, a laser molding press (not shown in the figure), a vacuum aluminizing device (not shown in the figure), a zinc sulfide evaporation device (not shown in the figure) and a reeling device (not shown in the figure), the composite film 11 is unreeled through the unreeling device, the reeling device is used for reeling, the composite film 11 is moved at a constant speed, wherein the local hollowing treatment is further performed on the stripping film 112 in the composite film 11 through the local hollowing device 4, and then the composite film 11 is coated, laser, aluminized and galvanized by the coating device 5, the laser molding press, the vacuum aluminizing device and the zinc sulfide evaporation device to prepare the multi-medium laser transfer anti-counterfeiting film 10, and a plurality of layers of anti-counterfeiting media are distributed on the anti-counterfeiting film and comprise two release information layers, an aluminum layer, a zinc sulfide layer and the like, so that the texture of the packaging paper is improved, and the anti-counterfeiting performance is good.

Specifically, unwinding device includes first unwinding roller 31, the winding device includes first winding roller 61, local fretwork device 4 is located first unwinding roller 31 and first winding roller 61 between, including work chamber 41, radio frequency laser 42, fan 43 and cooling platform 44, radio frequency laser 42 set up in work chamber 41, fan 43 sets up in one side of radio frequency laser 42, cooling platform 44 sets up with radio frequency laser 42 relatively to have the clearance that supplies complex film 11 to pass through with radio frequency laser 42.

Further, a first translation roller 7 which is in the same horizontal line with the first unwinding roller 31 is arranged on the film discharging side of the first unwinding roller 31, and a second translation roller 8 which is in the same horizontal line with the first winding roller 61 is arranged on the film feeding side of the first winding roller 61. And (3) placing the composite film 11 roll on the first unwinding roller 31, and winding one end of the composite film 11 roll to a winding device through the first translation roller 7, the cooling table 44 and the second translation roller 8. Make complex film 11 when removing, the warp radio frequency laser 42 carries out fretwork to complex film 11, still passes through fan 43 blows and peels off the membrane bits, avoids impurity to remain on complex film 11 to guarantee the quality of complex film 11. The composite film 11 is also contacted with the cooling platform 44, so that the composite film 11 can be cooled, the deformation of the composite film due to overhigh temperature can be avoided, and the quality of composite transfer can be further protected.

Specifically, the first translation roller 7 and the second translation roller 8 are arranged on the same horizontal line, and the composite film 11 is output from the first unwinding roller 31, passes through the first translation roller 7, surrounds the cooling table 44, passes through the second translation roller 8, and is wound by the first winding roller 61. More specifically, the top of the first translation roller 7 and the bottom surface of the first unwinding roller 31 are on the same horizontal line, the top of the second translation roller 8 and the bottom of the first winding roller 61 are on the same horizontal line, and when the composite film 11 is output, the first translation roller 7 plays a supporting role, so that the composite film 11 can be output at a constant speed. Through second translation roller 8 plays the supporting role, more does benefit to first wind-up roll 61 and carries out the rolling, still plays certain pulling force effect, makes the complex film 11 of carrying to first wind-up roll 61 department more level and more smooth. The first translation roller 7 and the second translation roller 8 are both positioned higher than the cooling platform 44, so that the composite film 11 can move around the plane of the cooling platform 44 when being output, and the operation of the radio frequency laser 42 is facilitated.

Further, be provided with gas detector 45 in the work module 41, the waste gas exit of work module 41 sets gradually filter 46 and air exhauster 47, gas detector 45 is connected with filter 46 and air exhauster 47 electricity, and when gas detector 45 detected waste gas (OPP steam) concentration in work module 41 and reached the highest default (about concentration is 50% threshold value), air exhauster 47 began working, takes out waste gas from work module 41, and when the waste gas concentration in work module 41 was less than the highest default (about concentration is 10% threshold value), air exhauster 47 stopped working. While the exhaust gas is being drawn, the harmful gas is also filtered by the filter 46 to prevent the environment from being polluted. Specifically, the filter 46 is a wet filter.

Referring to fig. 6, the unwinding device further includes a second unwinding roller 32, the winding device further includes a second winding roller 62, the coating device 5 is located at one side of the second unwinding roller 32 and the second winding roller 62, and includes a coating liquid tank 51, a ceramic anilox roller 52, and an impression rubber roller 53, a portion of the ceramic anilox roller 52 is located in the coating liquid tank 51, the impression rubber roller 53 is disposed at one side of the ceramic anilox roller 52 and is in rolling contact with the ceramic anilox roller 52, both the ceramic anilox roller 52 and the impression rubber roller 53 rotate counterclockwise, and the first release coating or the second release coating is coated on the composite film 11 and is wound by the second winding roller 62. When coating is carried out, the second winding roller 62 winds the composite film 11 to enable the composite film 11 to move at a constant speed, the rotation direction of the impression rubber roller 53 is consistent with the moving direction of the composite film 11, and the rotation direction of the ceramic anilox roller 52 is opposite to the moving direction of the composite film 11, so that the leveling effect of the coating is good under the condition that the thickness of the coating is guaranteed to be thin.

The utility model discloses still correspondingly provide a preparation method of radium-shine transfer anti-counterfeit paper 20, as shown in fig. 7, it includes the step:

s10, providing a composite film compounded by a base film and a stripping film;

s20, locally hollowing out the stripping film through a radio frequency laser;

s30, sequentially preparing a local release information layer and a local aluminum layer in the hollow area on the composite film (as shown in figure 2);

s40, preparing a covering type release information layer on the base film with the local release information layer and the local aluminum layer;

s50, evaporating a zinc sulfide layer on the covering type release information layer to obtain the multi-medium laser transfer anti-counterfeiting film (shown in figure 1);

s60, coating a glue layer on the surface of the zinc sulfide layer, compounding the glue layer with paper, and peeling the base film to obtain the laser transfer anti-counterfeiting paper (as shown in figure 4).

The embodiment of the utility model provides a preparation method of radium-shine transfer anti-counterfeit paper 20 is simple easy to operate, and does not need through washing aluminium technology, has simplified operation process greatly, has reduced manufacturing cost, still avoids polluting the environment, and waste water treatment cost advantage such as big.

In step S10, the utility model discloses a hot melt adhesive is through dry-type complex method with base film 112 with peel off membrane 111 complex, is obtained complex film 11. The base film 112 is made of Polyethylene (PE), and the release film 111 is made of biaxially oriented polypropylene (OPP), but the two are not limited thereto, as long as the two have a melting point difference, and the other film is partially hollowed out on the other film. The thickness of the base film 112 is 10 mu-20 mu, and the thickness of the peeling film 111 is 8 mu-12 mu.

In this embodiment, the hot melt adhesive comprises the following main components: EVA resin, acrylic acid, polyurethane and vinyl acetate copolymer, and the adhesive capacity of the hot melt adhesive is adjusted by adding the EVA resin in proportion to be 0.7N.

Specifically, the step S20 includes:

s21, conveying the stripping film of the composite film downwards to a radio frequency laser;

s22, locally heating and hollowing the stripping film by a radio frequency laser, and blowing off stripping film scraps by a fan;

and S23, cooling the composite film.

In this example, a high pulse intensity of 10.6. mu. mCO was used₂The laser 42 is used for locally heating and hollowing the reel composite film 11 (as shown in FIG. 8), and can be hollowed into different patterns and character information according to the program design, at CO₂When the laser 42 works, the power of the laser is adjusted to be 30-100W, the running speed of the composite film 11 is 100-250m/s, and because of the special selectivity of the laser to different film materials, the temperature of the light spot area is rapidly increased to the melting point or even the boiling point of the stripping film 111, so that the laser-irradiated area on the stripping film 111 is gasified, and meanwhile, the layer of the base film 112 is not influenced.

Preferably, during the heating and hollowing, the peeling film 111 of the composite film 11 faces downward, and the blower 43 is started to blow off the impurities (mainly, the peeling film scraps) possibly occurring by using the high-speed airflow, so as to prevent the impurities from remaining on the composite film 11.

In step S23, a cooling platen is used to contact the composite film 11, and the cooling roll temperature is 10-20 ℃ to cool the base film 112 (i.e., PE film) of the composite film 11, so as to prevent the base film 112 from deforming due to heat conduction during gasification of the composite film 11. Specifically, install gas detector 45 in the work module 41 of gasification stripping film 11 (being the OPP membrane), detect OPP steam concentration in the work module 41, when setting for the high concentration 50% threshold value of steam, interlock start sets up the air exhauster 47 that sets up in work module 41 one side and takes out high concentration steam from work module 41, when setting for the low concentration 10% threshold value of steam, air exhauster 47 stop work, when taking out the steam in work module 41, still filters harmful gas through setting up filter 46 on the exhaust pipe.

Preferably, the step S30 includes:

s31, preparing a first release coating on the composite film;

s32, pressing laser patterns on the first release coating through a laser molding press to obtain a first release information layer;

s33, vacuum plating an aluminum layer on the first release information layer (as shown in fig. 2);

s34, peeling the peeling film to form a partial release information layer and a partial aluminum layer on the surface of the base film (as shown in fig. 3).

In the step S31, when the first release coating is coated, a anilox roller is used for reverse coating, a 250-mesh ceramic roller with little influence of temperature is used under the conditions that the environmental humidity is controlled to be 60% and the temperature is 25 ℃, and the coating viscosity of the first release coating is controlled to be 20-30 pa.s. When coating, the composite film 11 moves at the speed of 160m/min, the gap between the impression rubber roll 53 and the ceramic anilox roll 52 is adjusted to be 0.5-5mm, reverse coating (namely the ceramic anilox roll is opposite to the composite film 11) is adopted to reduce the using amount of a coating layer, improve the coating quality, facilitate leveling and solve the problem of poor dispersion. Through the utility model discloses coating method, can make first from type coating on the complex film 11, just first from type coating's coating weight 0.8g/m²。

Coating a first release coating, then performing laser mould pressing to form a laser pattern, setting the running average speed of the composite film 11 to be 90m/min, heating a laser mould pressing working roller to the temperature of 220 ℃, selecting a rubber roller with the hardness of 95HS, and adjusting the pressure of the imprinting rubber roller 53 to be 15KG/cm by driving a rubber roller motor (not shown in the figure) during the laser mould pressing². Meanwhile, the deviation information of the edge position of the die pressing working plate is identified by the aid of the double electric eyes, the deviation rectifying processor performs logical operation on the deviation information, control information is sent out, the synchronous motor is controlled to drive the winding and unwinding device mechanism of the composite film 11, and linear deviation and S-shaped deviation in the linear process of the composite film 11 are rectified.

When vacuum aluminum plating is carried out, a working cavity of vacuum plating equipment is vacuumized by a vacuum pumping system at 10^-2-10^-3Under the vacuum condition of Pa, high-frequency induction heating is adopted to heat an aluminum strip with the purity of 99.9 percent to be more than 1400 ℃, so that the metal aluminum is gasified, evaporated and ascended, and a baffle of a working cavity is pumped out, so that the aluminum steam meets the low-temperature composite film 11 to form an aluminum layer. Of preferred, the utility model adopts temperatureThe anilox roller at the temperature of-10 to 0 ℃ cools the composite film 11, so that the composite film is not deformed due to overhigh temperature. In the embodiment of the present invention, the thickness of the aluminum plating layer is 55-65nm, and for example, the thickness of the aluminum plating layer is about 55nm, 60nm, or 65 nm.

In step S34, the composite film 11 after being aluminized is baked in an oven at a temperature of 80 ℃, at which time the hot melt adhesive loses its adhesive ability, and the composite film 11 is peeled off, leaving the PE peeling film with the local portion being aluminized.

Since the adhesive force of the glue when the base film 112 and the release film 111 are combined is about 0.7N, the hot melt adhesive loses the adhesive force under the heating environment, and the peeling force of the first release layer and the base film 112 is much larger than that, only the release film 111 is peeled off when the release film 111 is peeled off. Furthermore, the vacuum aluminum plating is thin and has a small tension and is easily broken by an external force, so that when the peeling film 111 is peeled, the aluminum layer and the first release information layer in the hollow region of the peeling film 111 are left on the base film 112 to form the local release information layer 12 and the local aluminum layer 13 (as shown in fig. 3).

Coating a second release coating on the region of the base film 112 exposed after the partial aluminum layer 13 and the OPP film are peeled off to cover the base film 112 by step S40, which includes:

s41, preparing a second release coating on the base film with the local release information layer and the local aluminum layer;

and S42, pressing laser patterns on the second release coating through a laser molding press to obtain the covering type release information layer (shown in figure 1).

In some embodiments, when the second release coating is coated in step S41, an anilox roller is also used for reverse coating, the ambient temperature and humidity can be controlled to be about 60% of humidity, the temperature is controlled to be 25 ℃, a 150-mesh ceramic roller with little influence of temperature is used, the coating viscosity of the second release coating is controlled to be 20-30pa.s, the composite film 11 moves at a speed of 160m/min during coating, and the reverse coating (i.e. the ceramic anilox roller 52 is opposite to the composite film 11) is used to reduce the amount of the coating layer, improve the coating quality, facilitate leveling, and solve the problem of poor dispersion. Through the utility model is implementedThe coating method of example, a second release coating may be formed on the composite film 11. By the coating method, a uniform second release coating can be prepared on the composite film 11, and the coating weight of the second release information coating is 1.3g/m²。

Preferably, the first release coating and the second release coating can have the same composition, and mainly comprise 25-35 parts by weight of cellulose resin, 20-30 parts by weight of acrylic resin, 20-25 parts by weight of ethyl ester, 20-25 parts by weight of butanone, 1-5 parts by weight of microcrystalline wax and the like.

In some specific embodiments, the first release coating and the second release coating comprise 30 parts of cellulose resin, 24 parts of acrylic resin, 22 parts of ethyl ester, 22 parts of butanone, 2 parts of microcrystalline wax and the like which are main components of the release information layer.

In some embodiments, the step S42 includes: setting the running average speed of the composite film 11 to be controlled at 90m/min, heating the laser mould pressing working plate roller at 170 ℃, selecting the rubber roller with the hardness of 95HS, and adjusting the rubber roller pressure to be 30KG/cm by driving a rubber roller motor². The double-electric-eye recognition die pressing working plate edge position deviation information is adopted, the deviation correction processor carries out logic operation on the deviation information, control information is sent out, the synchronous motor is controlled to drive the composite film 11 winding and unwinding device mechanism, and linear deviation and S-shaped deviation in the composite film 11 linear process are corrected.

Further, after the step S40 and before the step S50, the method further includes:

s401, carrying out corona treatment on the covering type release information layer.

Specifically, the corona power is 2-5W. The embodiment of the utility model provides a preferentially set corona power in 3W, is guaranteeing that the overlay type reaches under the prerequisite of specified value from the surface adhesion of type information layer 14, is unlikely to puncture the overlay type from type information layer 14.

Furthermore, step S50 is to use vacuum evaporation of zinc sulfide, during the evaporation, the vacuum pumping system first pumps the working chamber to vacuum, 10^-2-10^-3Under the vacuum condition of Pa, high-frequency induction is adopted to heat zinc sulfide powder with the purity of 99.9 percent to 1000 DEG CThe zinc sulfide is vaporized and evaporated and rises, and then the baffle plate of the working chamber is drawn out, so that the temperature of the zinc sulfide steam is lower, the film is peeled off, and the liner becomes a zinc sulfide layer 15.

Preferably, the anilox roller is used to cool the composite film 11 at a temperature of-10 to 0 ℃ so that it is not deformed by an excessive temperature. In the embodiment of the present invention, the thickness of the zinc sulfide plating layer 15 is 55-70nm, and for example, the thickness of the zinc sulfide plating layer 15 is about 55nm, 60nm or 70 nm.

The utility model discloses an above-mentioned mode has made the radium-shine anti-fake membrane 10 that shifts of multimedium, and the local radium-shine pattern of preventing counterfeiting from on the type information layer 12 presents through local aluminium lamination 13, and the radium-shine pattern zinc sulfide layer 15 of preventing counterfeiting from on the type information layer 14 of overlay type presents to have dual anti-fake, have the metal of aluminium again and feel, promoted the quality of packing product.

When the laser transfer security paper 20 is manufactured, the step S60 includes: uniformly coating the single-component solvent-free glue on the surface of the zinc sulfide layer 15 by using a 200-mesh steel roller to form a glue layer, then attaching the paper 21 to the surface of the glue layer, drying and compounding, and finally stripping the composite film 11 from the surface of the covering type release information layer 14 to obtain the laser transfer anti-counterfeiting paper 20 which is a laser transfer anti-counterfeiting paper with a plurality of layers of media.

The embodiment of the utility model provides an in, adopt 200 meshes steel rod single component solvent-free glue evenly to coat on 15 surfaces on zinc sulfide layer, the coating weight control is about 3.5 g/square meter, compound with paper 21, and the solvent-free glue is compound does not have the VOCs and discharges, and natural drying under humidity 70 and temperature 40 ℃ condition, the energy consumption volume is few, and the pliability is more superior, good antiknock look performance.

To sum up, the utility model provides a radium-shine transfer anti-counterfeiting membrane, radium-shine transfer anti-counterfeiting paper and production facility, wherein radium-shine transfer anti-counterfeiting paper is including stacking gradually paper, glue film, zinc sulfide layer, the overlay type that sets up from type information layer, local aluminium lamination and local release type information layer, the local shape from type information layer and local aluminium lamination is the same, the overlay type covers from type information layer local aluminium lamination and adjacent local aluminium lamination fretwork part make radium-shine transfer anti-counterfeiting paper have higher anti-counterfeiting performance, be favorable to improving the grade and the added value of product, have higher product competitiveness.

It should be understood that equivalent alterations and modifications can be made by those skilled in the art according to the technical solution of the present invention and the inventive concept thereof, and all such alterations and modifications should fall within the scope of the appended claims.

Claims (10)

1. The utility model provides a radium-shine transfer anti-counterfeiting membrane, its characterized in that, leaves type information layer, local aluminium lamination, overlay type from type information layer and zinc sulfide layer including the base film, the part that stack gradually the strippable of setting, the part is the same from the shape of type information layer and local aluminium lamination, the overlay type is in from the type information layer cover on the base film that local aluminium lamination and adjacent local aluminium lamination fretwork part expose.

2. The laser transfer anti-counterfeiting film according to claim 1, wherein the thickness of the local release information layer is 30-70 nm, and the thickness of the local aluminum layer is 50-90 nm.

3. The laser transfer anti-counterfeiting film according to claim 1, wherein the thickest part of the covering type release information layer has a thickness of 90-250 nm, and the thickness of the zinc sulfide layer is 40-80 nm.

4. The utility model provides a radium-shine transfer anti-counterfeit paper, its characterized in that, includes that paper, glue film, zinc sulfide layer, the overlay type that stacks gradually the setting are from type information layer, local aluminium lamination and local from type information layer, the local shape from type information layer and local aluminium lamination is the same, the overlay type is in from type information layer local aluminium lamination and adjacent local aluminium lamination fretwork part.

5. The laser transfer anti-counterfeiting paper according to claim 4, wherein the thickness of the local release information layer is 30-70 nm, and the thickness of the local aluminum layer is 50-90 nm.

6. The laser transfer anti-counterfeiting paper according to claim 4, wherein the thickest part of the covering type release information layer has a thickness of 90-250 nm, and the thickness of the zinc sulfide layer is 40-80 nm.

7. The utility model provides a production facility for making radium-shine transfer anti-counterfeiting membrane, radium-shine transfer anti-counterfeiting paper which characterized in that, including set gradually be used for providing the unwinding device of complex film, be used for making the local fretwork device of the local fretwork of stripping film on the complex film, be used for preparing first coating unit, radium-shine moulding press, vacuum aluminizing device, zinc sulfide coating by vaporization device and coiling mechanism from type coating with the second.

8. The production equipment for manufacturing the laser transfer anti-counterfeiting film and the laser transfer anti-counterfeiting paper as claimed in claim 7, wherein the unwinding device comprises a first unwinding roller, the winding device comprises a first winding roller, the local hollow device is located between the first unwinding roller and the first winding roller and comprises a working chamber, a radio frequency laser, a fan and a cooling table, the radio frequency laser is arranged in the working chamber, the fan is arranged on one side of the radio frequency laser, and the cooling table is arranged opposite to the radio frequency laser and has a gap for a composite film to pass through with the radio frequency laser.

9. The production equipment for manufacturing the laser transfer anti-counterfeiting film and the laser transfer anti-counterfeiting paper according to claim 8, wherein a gas detector is arranged in the working cabin, a filter and an exhaust fan are sequentially arranged at a waste gas outlet of the working cabin, and the gas detector is electrically connected with the filter and the exhaust fan.

10. The production equipment for manufacturing the laser transfer anti-counterfeiting film and the laser transfer anti-counterfeiting paper according to claim 8, wherein the unwinding device further comprises a second unwinding roller, the winding device further comprises a second winding roller, the coating device is positioned on one side of the second unwinding roller and one side of the second winding roller and comprises a coating liquid tank, a ceramic anilox roller and an embossing rubber roller, one part of the ceramic anilox roller is positioned in a coating liquid in the coating liquid tank, the embossing rubber roller is arranged on one side of the ceramic anilox roller and is in rolling contact with the ceramic anilox roller, the ceramic anilox roller and the embossing rubber roller both rotate anticlockwise, a first release coating or a second release coating is coated on the composite film, and the composite film is wound by the second winding roller.

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