JPH09216281A - Film bonded can body and its production - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a film bonded can body excellent in appearance free from wrinkles or cracks and generating no levitation of the film and to easily produce the same. SOLUTION: In a film bonded can body wherein a decorative thermoplastic resin film 2 having a printing layer 2b and an adhesive layer 2c formed to one surface thereof is bonded to the outside body surface of a metal can body 1 in such a state that both end parts of the film are overlapped through the adhesive layer 2c, an overcoat layer 3 cured by radiation is formed to the outer surface of the bonded decorative thermoplastic resin film 2. The overcoat layer 3 is formed in coating film thickness less than that of other part on the film overlapped part 6 and the surface of the overcoat layer covering the film stepped part at the film overlapped part 6 is leveled so as to form a slope 5 gentle in the circumferential direction of the can body surface.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a metal can body in which a decorative film is attached to the outer surface of a can body in a state where both ends thereof are overlapped with each other, and a method for manufacturing the same.

[0002]

2. Description of the Related Art A so-called two-piece can made of tin or aluminum, which is a seamless metal can with an integrated bottom, is usually formed by squeezing and ironing to form a can body, followed by washing and surface treatment, followed by painting and printing. I am giving it. The mainstream printing method is a dry offset printing machine. However, in this type of printing, all colors are applied from a common blanket, so the number of colors is limited to at most 5 colors. Halftone printing was almost impossible to avoid overlapping lines.

On the other hand, in recent years, as demands from customers have become stricter, halftone printing has become a considerable level by making ingenuity in plate making and stricter printing conditions even in dry offset printing. Has been improved to. However, products are diversifying due to changes in consumption trends and needs, and there is a demand for beautiful products with a higher print quality that is required.

In order to meet such demands, as an alternative to a can obtained by directly printing on a metal can body, a preprinted thermoplastic resin film such as polyester is attached to the outer surface of the metal can body. Various cans made by wearing have been proposed. In addition to offset printing, gravure printing, flexographic printing, etc. can be selected as the method of making the printing film.These printing methods have a high decorative effect compared to the conventional dry offset printing method. The quality is quite good, and since it is printed on a continuous thermoplastic resin film instead of a can, high-speed printing can be expected, and it has advantages that conventional dry offset printing does not have.

As a method for producing a can having a high decorative effect by heat-adhering the preprinted thermoplastic film as described above, JP-A-52-24790 and JP-A-3-230 are known.
The methods described in Japanese Patent Application Laid-Open No. 940, Japanese Patent Application Laid-Open No. 4-57747, Japanese Patent Application Laid-Open No. 7-89552 and the like are known. These will be briefly described. JP-A-52-2
According to the method described in Japanese Patent No. 4790, a printed film is attached to the can body surface of a can body that has been subjected to neck-in processing and flange processing, and the film is heat-shrinked to match the contour of the neck-in processed portion. Is the way.

In the method described in Japanese Patent Laid-Open No. 3-230940, a metal plate is first drawn or drawn and ironed to form a can body having an open end, and the can body surface of the can body is formed. This is a method in which a printed film is attached, and after that, neck-in processing and flange processing are performed on the opening end portion. And in the method described in this publication,
It is said that a thermoplastic resin film having an overcoat layer for protecting the printed layer is preferable.

Further, the method described in Japanese Patent Application Laid-Open No. 4-57747 is a method of performing neck-in processing or flange processing after adhering a printed film, and in this method, neck-in processing or flange processing. At the time of printing, in order to prevent wrinkles of the metal can on both sides of the film stacking part, the film at the planned film stacking part (corresponding to the cut point of the film) is stretched with a cylinder etc. The thickness of the overlapping part of the thermoplastic resin film of the finished film is reduced.

The method described in JP-A-7-89552 is similar to the method described in JP-A-3-230940 and JP-A-4-57747, and a printed thermoplastic resin is used. It is a method to perform necking and flange processing after attaching the film to the metal can body, but when attaching the film, overlap both ends of each other, or butt both ends of the film,
In this state, the adhesive provided on the film is used to thermally adhere to the outer surface of the can body of the heated metal can body.
Further, in order to cure the adhesive, it is further heated or irradiated with an electron beam.

[0009]

When a printed thermoplastic resin film is attached to a metal can body, it is added to prevent air entrapment and wrinkles from occurring and to attach the film securely. It is necessary to attach the film to the metal can body while applying pressure. However, the above-mentioned Japanese Patent Laid-Open No. 52-247.
In the method described in Japanese Patent Publication No. 90, the neck-in processing or the flange processing of the metal can body is performed before the printed thermoplastic resin film is adhered. It is difficult to insert into the metal can body a mandrel that is squeezed and has an outer diameter approximately equal to the inner diameter of the can body. For this reason, this method cannot increase the pressure applied to attach the film, and as a result, air is easily trapped between the film and the metal can body to cause poor adhesion, and the film is not neck-in. There is a problem that wrinkles are likely to occur in the neck-in portion when heat shrinks along the contour of the portion.

On the other hand, in the method described in Japanese Patent Laid-Open No. 3-230940, since the printed thermoplastic resin film is attached to the metal can body and then neck-in processing and flange processing are performed, the printing layer It is said that it is preferable to provide an overcoat layer for protection, and rather, the overcoat layer is considered essential. However, when both ends of the film are overlapped when attaching the film,
The slip agent such as silicone and wax contained in the overcoat layer hinders the adhesion of the film overlapping parts, and as a result, the film overlapping is performed during post-molding such as neck-in processing after film adhesion. There is an inconvenience that the part is easily peeled off. If an overcoat is not applied to eliminate such inconvenience, the outer surface of the can body becomes less slippery and the transportability of the can decreases, and the strength of the printing layer decreases and scratches occur. Problems such as easy sticking occur.

Further, according to the method disclosed in Japanese Patent Laid-Open No. 4-57747, the superposed portion of the printed thermoplastic resin film is stretched and thinned, so that the running of the film must be temporarily stopped for the stretching. Therefore, there is a problem in that the speeding up of film attachment is impeded.

Further, according to the method disclosed in Japanese Patent Laid-Open No. 7-89552, when the printed thermoplastic resin film is attached to the metal can body, if both ends of the film are overlapped with each other, the above-mentioned special feature is used. Similar to the method described in Kaihei 3-230940, there is a problem that the adhesiveness of the superposed portion is obstructed by the overcoat and peeling easily occurs at this portion. In addition, instead of this, when sticking both ends of the film by abutting, since the sticking is performed under heating and the film tends to shrink, there is a gap between the abutting ends of the film, and this part Therefore, there is a disadvantage that the metal base is exposed and rust is generated, or the abutting end of the film is lifted up in the sterilization process to cause peeling. Furthermore, since the distance between the abutting ends of the film is not always constant, the appearance is impaired.

The present invention has been made in view of the above circumstances, and prevents occurrence of wrinkles during post-forming such as neck-in processing and flange processing after sticking a printed thermoplastic resin film, In addition, it improves the slipperiness and scratch resistance of the outer surface of the can body, and can prevent rust from occurring without applying a base coat to the metal can body before attaching the film, and also prevents vapor and water during sterilization. It is an object of the present invention to provide a film sticking can and a method for producing the same, which can prevent the film from entering the lower surface side of the film and prevent the film from rising and peeling.

[0014]

In order to achieve the above-mentioned object, the invention of claim 1 forms a printing layer and an adhesive layer on one surface of the outer can body surface of a metal can body. The decorative thermoplastic resin film is adhered in a state that the both ends of the decorative thermoplastic resin film are adhered to each other via the adhesive layer, and the external surface of the decorative thermoplastic resin film is adhered. On the side, a radiation-cured overcoat layer is formed, and the overcoat layer is formed on the film overlapping portion to have a thinner coating film thickness than other portions, and the step of the overcoat layer due to the film overlapping is formed. Is leveled, and the surface of the overcoat layer that covers the film step portion in the overlapping portion of the film is formed in a gentle slope shape in the circumferential direction of the can body surface. Than it is.

Therefore, since the decorative film itself is not provided with the overcoat layer, the films are surely adhered to each other at the film overlapping portion, and there is no inconvenience such as peeling at this portion. Further, since the outer surface of the can body is covered with the overcoat layer, damage and peeling of the film can be prevented, and the can body can be easily transported. Furthermore, the steps of the overcoat layer due to the overlapping of the films are leveled, and the overcoat layer at the film overlapping part is formed in a gentle slope in the circumferential direction, so that it can be applied to the neck of the can body at a later step. When performing neck-in processing such as die neck processing, the gap between the outer surface of the can body and the die neck molding die becomes as uniform as possible, and as a result, stress concentration of compressive force acting in the circumferential direction is prevented, Wrinkles on the neck are prevented. And since the coating material forming the overcoat layer is a radiation curable resin, it is not necessary to heat the can body when curing the overcoat layer, so that the heat shrinkage of the decorative film is prevented and a can body with an excellent appearance is obtained. Obtainable.

Further, in the present invention, as described in claim 2, in the radial direction of the metal can body, the outer surface of the overcoat layer at the film overlapping portion and the general surface other than the film overlapping portion are in the radial direction. Difference, that is, the step difference of the overcoat layer is set to 80% or less of the thickness of the film including the printing layer and the adhesive layer.

When the leveling of the overcoat layer at the film overlapping portion is performed to this extent, wrinkles and the like due to the compressive force in the circumferential direction during neck-in processing can be more reliably prevented.

Further, in the present invention, as described in claim 3, the overcoat layer and the adhesive layer can be made of an electron beam curable resin.

With such a constitution, the adhesive layer can be simultaneously cured in the curing process of the overcoat layer by electron beam irradiation, so that the so-called adhesive curing step of independently heating and curing the adhesive layer can be omitted. The process can be shortened.

Further, the invention according to claim 4 is a thermoplastic resin film for decoration in which a printed layer and an adhesive layer made of a thermosetting resin are formed on one surface of the outer can body surface of a metal can body. , After sticking through the adhesive layer, in the method for producing a film sticking can body for performing neck-in processing and flange processing on the opening end of the can body, a heating step of heating the can body, and A film cutting step of previously cutting the decorative thermoplastic resin film to a length longer than the circumference of the can body, and the cut decorative thermoplastic resin film is bonded to the heated can body surface of the can body. A film sticking step in which both ends of the decorative thermoplastic resin film are heat-bonded through the adhesive so that they overlap each other, and there is no solvent and fluidity on the outer surface side of the decorative thermoplastic resin film after sticking. UV curable tree And an overcoat application step of applying an overcoat paint consisting by irradiating ultraviolet rays on the outer surface side of the can body, curing the overcoat paint,
The method is characterized by including an ultraviolet irradiation step of forming an overcoat layer and an adhesive curing step of curing the adhesive.

Therefore, according to the method of the present invention, when the decorative thermoplastic resin film is attached to the can body, both ends of the film overlap each other, but since the film itself is not provided with the overcoat layer, it is overlapped. The films are surely attached to each other even at the joining portion. The overcoat paint is applied after the film is attached,
In addition, since the film adhered to the film is cured by being irradiated with ultraviolet rays, thermal contraction does not occur, and a film-attached can body having an excellent appearance without wrinkles can be obtained.

Further, the invention according to claim 5 is a thermoplastic resin for decoration in which a printed layer and an adhesive layer made of an electron beam curable resin are formed on one surface of the outer can body surface of a metal can body. The film, after sticking through the adhesive layer, in the method for producing a film sticking can for performing neck-in processing and flange processing on the opening end of the can body, a heating step of heating the can body, and A film cutting step of previously cutting the decorative thermoplastic resin film to a length longer than the circumference of the can body, and the cut decorative thermoplastic resin film is bonded to the heated can body surface of the can body. Electron beam with solvent-free fluidity on the outer surface side of the decorative thermoplastic resin film after the film is adhered through the adhesive, and the decorative film is thermally adhered so that both ends of the decorative film overlap each other. From curable resin And an overcoat applying step of applying an overcoat paint, and irradiating an electron beam from the outer surface side of the overcoat paint to cure the overcoat paint to form an overcoat layer and simultaneously cure the adhesive. An electron beam irradiation step is included.

Therefore, in the invention of claim 5, in addition to the invention of claim 4 described above, the adhesive layer is formed of a resin which is cured by being irradiated with an electron beam similarly to the overcoat layer. The adhesive layer can be cured in the process of curing the coat layer, and as a result, a single process for curing the adhesive layer can be omitted, and the process can be shortened.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Next, the present invention will be described more specifically. The can body 1 targeted by the present invention is made of metal, and the metal plate as a material thereof is an aluminum plate, surface-treated steel plate such as tin-free steel, tin plate, chrome plated steel plate, aluminum plated steel plate, nickel plated steel plate. Other various alloy-plated steel sheets can be used. Further, as shown in FIG. 1, the can body 1 can be a can body with a bottom formed by integrally forming a can bottom and a can body such as a squeezed can, a squeezed iron can, and an impact can, that is, a two-piece can. . At the open end of this can body, neck-in processing and flange processing are finally performed to form a neck portion 1a and a flange portion 1b.

A decorative film 2 attached to the can body 1.
As the thermoplastic resin film is used, specifically, a polyethylene terephthalate resin, a polyester-based resin such as polybutylene terephthalate resin, a copolymerized polyester-based resin including a copolymer of polyethylene terephthalate and isophthalic acid, polypropylene Transparent polymer resin simple substance selected from resin, polycarbonate resin, polystyrene resin, polyolefin resin, vinyl chloride resin, polyvinylidene chloride copolymer, etc.
Alternatively, a thermoplastic resin film 2a made of a composite of the above resins is used. In particular, it is preferable to use a polyethylene terephthalate resin having a heat-resistant property, in which the film spreads to some extent in the circumferential direction of the can 1 at a linear pressure of 60 kgf / cm in the attaching step. The thickness of the film 2a can be appropriately determined, and as an example, a film having a thickness of about 10 to 30 μm can be used.

A print layer 2b and an adhesive layer 2c are sequentially formed on one surface of the film 2a. That is, a decorative print is applied to one surface of the resin film 2a, and an adhesive layer 2c is provided on the surface of the print layer 2b. For the printing, an ink made of a thermosetting urethane resin is used, and printing by gravure printing, flexographic printing, offset printing or the like is performed.

For the adhesive layer 2c, a thermosetting adhesive is used, which is easily adhered by heat and pressure and has good adhesion to ink. In particular, the glass transition point (Tg) at which the adhesive layer is easily projected due to the pressure applied in the main bonding step is -1.
A thermosetting resin having a good fluidity at 0 ° C. to + 40 ° C. is preferable, and an adhesive containing a polyester resin, an epoxy resin and an amino resin is usually used. Also, the adhesive layer 2
It is preferable that c is provided on the entire surface of the printed layer 2b. The adhesive is thickly applied at 90 to 110 mg / dm ² . The entire surface is coated with at least 50 mg / dm ² .

As a specific example of the electron beam (radiation) curable adhesive, stress relaxation is added to a resin composition in which 2 to 30 parts by weight of a polyester oligomer having an unsaturated double bond is mixed with 100 parts by weight of a polyester resin. 0.5 to 25
An electron beam curable adhesive obtained by adding 0 PHR (parts by weight to 100 parts by weight of resin) is used.

In the present invention, the overcoat layer 3 is formed on the decorative film 2 attached to the outer surface of the can body of the can body. The overcoat layer 3 is cured by radiation (electron beam), and examples of paints therefor include epoxy acrylate resin, polyester acrylate resin, polyurethane acrylate resin, polyether acrylate resin, and polybutadiene acrylate resin. Any resin having a relatively high molecular weight, such as a resinous one, to a low monomeric one, which exhibits a polymerization reaction by radiation may be used. The radiation curable resin may be used alone or as a mixture of two or more kinds.

In the step portion 4 formed by overlapping the both ends of the film 2, the overcoat paint flows to form a gentle inclined surface 5. In addition, the film overlapping section 6
The thickness OBD of the overcoat layer 3 in the above is the amount of protrusion of the outer surface of the portion relative to other portions, that is, in the radial direction between the outer surface of the overcoat layer 3 and other general surface at this film overlapping portion. It is preferable that the dimensional difference T2 of the above is 80% or less of the thickness T1 of the film 2 including the printing layer 2b and the adhesive layer 2c. This is to prevent wrinkles from occurring during neck-in processing.

The relationship between the respective dimensions is as follows with reference to FIG.

T2 = (2T1 + OBD)-(T1 + OBS) T2 ≦ 0.8T1 T1 = film thickness + printing layer thickness + adhesive layer thickness OBD = overcoat coating film thickness on the overlapping portion OBS = film 1 layer Above overcoat coating thickness Although these resins can be used as they are as overcoat paints, use a photopolymerizable monomer as a reactive diluent in order to reduce the viscosity and increase their fluidity. You can Specific examples thereof include monofunctional monomers; 2-hydroxyethyl acrylate, tetrahydrofurfuryl acrylate, and the like, difunctional monomers; dicyclopentenyl acrylate, dicyclopentenialoxyethyl acrylate, 1,3-butanediol diacrylate. Trifunctional or higher functional monomers such as 1,4-butanediol diacrylate, 1,6-hexanediol diacrylate, diethylene glycol, neobenthyl glycol diacrylate, and tripropene glycol diacrylate; trimethylolpropane triacrylate and ventaerythritol. Examples thereof include triacrylate and diventaerythritol hexaacrylate.

The viscosity is 200 to 350 cp.
(Ford cup No. 4, 60 to 90 seconds at 25 ° C.). When the viscosity is less than 200 cp, the viscosity is too low, and when the overcoat paint is applied, the paint is likely to sag between the application roll and the can 1, and the application work becomes difficult. If the viscosity exceeds 350 cp, it becomes difficult to achieve thinning and leveling due to the flow of the overcoat paint. By adjusting the viscosity of the overcoat paint in this way, the overcoat paint flows after application and forms a gentle inclined surface 5 at the film overlapping portion 6 and has a desired thickness.

As means for curing the overcoat paint,
Irradiation can be employed. Here, radiation means radiation in a broad sense, and includes all electromagnetic waves and particle beams. Therefore, the overcoat paint can be cured by irradiating electron beams such as X-rays, gamma rays, and beta rays. Irradiation with these electron beams is suitable when the coating film is thick. In order to carry out the curing operation easily with simple equipment, ultraviolet rays (U
V radiation) irradiation is adopted. The ultraviolet irradiation is suitable when the coating film is thin.

When ultraviolet rays are used as radiation,
It is preferable to incorporate a photopolymerization initiator into the overcoat coating composition. Specific examples of the photopolymerization initiator include:
Acetophenone, benzophenone, Michlerkent, benzine, benzoin, benzoinisobutyl ether, benzine methyl ketal, tetramethyl thiuram sulfide, azobisisobutyronitrile, benzoyl peroxide, di tert-butyl peroxide, 1-hydroxycyclohexyl phenyl ketone, 2 -Hydroxy-2-methyl-1-phenyl-propan-1-one,
Examples thereof include 1- (4-isoprofilephenyl) -2-hydroxy-2-methylpropan-1-one, 2-chlorothioxanthone, and methylbenzoyl formate. These photopolymerization initiators may be used alone or in combination of two or more kinds.

The curing time depends on the thickness of the decorative film 2, the radiation source, the photoinitiator, the reactive diluent, and the distance between the radiation source and the coating surface to be cured, but the production efficiency is improved. Therefore, 0.1 second to 1.0 second is preferable.

In the method of the present invention, the above-mentioned decorative film 2 is adhered to the can body and then the overcoat paint is applied thereon. As the coating method, a roll coater, a gravure coater, a spray coating method or the like is adopted.

In the method of the present invention, as an example, as shown in the process chart of FIG. 5, a thermoplastic resin for decoration in which a printing layer 2b and an adhesive layer 2c are provided on the surface of the metal can 1 which is in close contact with the can body surface. The resin film 2 is cut longer than the circumference of the can body. This is attached to the can body of the metal can body 1 that has been heated and heated. In that case, as shown in FIG. 6, both ends of the film 2 may overlap with each other to form a step corresponding to the film thickness, and a step gap 7 may be formed inside thereof. When the can body surface to which the film 2 is attached is pressed with a high pressure inside the stepped void portion 7, the adhesive layer 2c protrudes, and as a result, the adhesive layers 2c fuse together. Therefore, the step gap 7 is filled with the adhesive, and the film end is surely attached to the body surface of the can. After that, an overcoat paint made of a radiation curable resin is applied to the outer peripheral surface of the decorative film 2.

As shown in FIG. 3, the overcoat paint was applied to the outer peripheral surface of the film by flowing into the film step portion 4, leveling this portion, and irradiating with radiation after a lapse of a predetermined time required for this. The overcoat paint is cured to form a uniform overcoat layer 3 on the entire circumferential surface of the can body.

Therefore, the overcoat layer 3 is
The surface of the overcoat layer, which is formed on the film overlapping portion 6 to have a thin coating film thickness and covers the film step portion 4 of the film overlapping portion 6, is leveled to a gentle slope, and there is no step in appearance. looks like. That is, the outer surface of the film of the printed thermoplastic resin film-adhered can looks like a uniform surface without unevenness over the entire circumference of the can barrel because the overcoat layer in the film overlapping portion is leveled.

Further, the upper surface of the lower film of the overlapping portion at both ends of the film (the surface of the upper film which is in contact with the adhesive layer)
Since there is no overcoat layer containing a lubricant such as silicone or wax, the adhesion between the films 2 is good. Further, since the overcoat layer 3 made of a radiation curable resin is formed on the entire outer peripheral surface of the film of the can after the film is attached, the coating film on the surface of the can body becomes harder and the overcoat paint is made of the radiation curable resin. Therefore, it is not necessary to heat the film for curing, and deformation of the decorative film due to heat shrinkage can be prevented.

After the decorative film 2 is attached to the can body as described above, the can body 1 is sent to the next step, and neck-in processing (especially die-neck processing) is applied to the opening end of the film-attached can. Give. In that case, since the entire circumference of the can body is covered with the overcoat layer 3 and the overcoat layer in the film overlapping portion is formed in a gentle slope shape and leveled, the neck portion is circumferentially oriented. It is possible to prevent the stress concentration of the compressive force acting on, and to prevent wrinkles in the neck portion and opening of the film end portion. Furthermore, it is possible to prevent rusting and lifting of the film 2 at the film-attached joint portion, which is likely to occur in the sterilization process, and the step portion 4 on the upper layer side can be prevented.
Also, because it is beautifully finished, the appearance quality can be improved.

When an electron beam curable overcoat is applied to the can body surface of a film-coated can, if an electron beam curable resin is used as an adhesive, the overcoat paint is cured by electron beam irradiation. At the same time, the curing of the adhesive can be accelerated. That is, the heat curing step of the adhesive can be omitted, and the adhesive can be cured together in the electron beam step. A process drawing in that case is shown in FIG.

Next, a device for carrying out the present invention will be briefly described. FIG. 8 is a schematic view showing the entire structure thereof, in which a large number of mandrels 10 are arranged on the circumference of a predetermined turning radius. It is arranged so as to turn at regular intervals. These mandrels 10 are cylindrical members having a diameter slightly smaller than the inner diameter of the target metal can body 1, and are configured so as to be able to rotate about their respective central axes.

On the other hand, the metal can body 1 fitted and held on the outer periphery of the mandrel 10 is a so-called two-piece can body 1 which is formed as a cylindrical body with a bottom by, for example, drawing and ironing an aluminum disc. There is no neck-in processing or flange processing. Conveying means (not shown) for arranging and conveying the two-piece cans 1 in a line is arranged to extend to the outer peripheral side at a predetermined position of the circumference on which the mandrel 10 revolves, and the two-piece cans conveyed by the conveying means. Reference numeral 1 denotes a mandrel 10 in which the bottom of the can is pushed by pushing means (not shown) and is fitted into the mandrel 10.
In contrast, the two-piece cans 1 are handed over one by one.

The mandrel 10 is continuously swung in the direction of the arrow in FIG. 8, and the mandrel 10 is swung in the turning direction of the mandrel 10 from the supply station 11 of the two-piece can 1 in the circumferential direction. The heating device 12 is arranged outside over a predetermined range. The heating device 12 is for heating and raising the temperature of the two-piece can 1 held by the mandrel 10.
As an example, a high frequency induction heating device can be adopted. The mandrel 10 is configured to rotate on its axis in a range where the heating device 12 is arranged.

The mandrel 10 is attached to the heating device 12.
The portion adjacent to the front side in the turning direction of is a temporary adhesion station 13, which is the temporary adhesion station 13 on the can body surface of the heated two-piece can 1, and the printing layer 2b and the adhesion layer 2c are formed on one surface of the temporary adhesion station 13. The decorative film 2 made of a thermoplastic resin formed in order is attached. In the temporary bonding station 13, the sticking roll 14 is arranged outside the turning radius of the mandrel 10. This sticking roll 14 has a plurality of the decorative films 2 cut longer than the peripheral length of the can body surface of the two-piece can 1, with the adhesive layer 2c serving as the outer surface, and the outer peripheral surface thereof having a constant interval. The decorative film 2 adsorbed on the outer surface of the mandrel 10 is adhered to and held on the can body surface of the two-piece can 1 by rotating the mandrel 10 in synchronization with the turning of the mandrel 10. In that case, the adhesive pressure can be adjusted to an appropriate pressure by adjusting the distance between the sticking roll 14 and the mandrel 10, and an example thereof is a linear pressure of about 30 kgf / cm. As the means for adsorbing and holding the decorative film 2, various conventionally known means can be adopted, and for example, vacuum adsorbing may be adopted.

A main bonding station 15 is provided on the opposite side of the heating device 12 with respect to the temporary bonding station 13. The main bonding station 15 is a place where pressure is applied to the decorative film 2 attached to the can body surface of the two-piece can 1, and processing is performed to more firmly attach the decorative film 2 to the outside of the turning radius of the mandrel 10. Pressure roll 16
Is arranged. The pressure roll 16 receives a pressing force toward the mandrel 10, and the mandrel 10
The two-piece can 1 is configured to rotate in synchronism with the fitted two-piece can 1 or to rotate by a frictional force between the two-piece can 1. This pressure roll 16 is such that the two-piece can 1 is not allowed to cool, that is, the adhesive layer 2 of the decorative film 2.
It is arranged close to the temporary bonding station 13 within a range in which the temperature does not drop to such an extent that c solidifies. The applied pressure is 1.5 to 2.0 times the applied pressure at the temporary bonding station 13, and the linear pressure is at least 40 kg.
It is set to f / cm.

Next, an overcoat station 17 is provided on the opposite side of the main adhesion station 15 from the temporary adhesion station 13. The overcoat station 17 is a portion where the decorative film 2 is firmly attached to the can body surface at the main bonding station 15 and then an overcoat paint made of a radiation curable resin is applied to the outer peripheral surface of the decorative film 2. The overcoater 18 is arranged outside the turning radius of the mandrel 10. The overcoater 18 is a roll coater composed of an applicator roll 19 and two metering rolls 20, and the applicator roll 1
By rotating the mandrel 9 in synchronism with the turning of the mandrel 10, the paint measured in the small gap between the two metering rolls 20 is transferred to the applicator roll 19, and the overcoat paint on the surface thereof is transferred to the two-piece can 1 Is applied to the entire outer peripheral surface, that is, the outer surface of the decorative film 2 attached to the can body surface.

When the time for lowering the temperature of the film-attached can 1 cannot be secured, as shown in FIG.
Between the film attaching step and the overcoat station 17, there is provided a transfer unit 25 in which pockets 24 are provided on the circumference at constant intervals, and pneumatic means such as air (not shown) is used. Then, the film-attached can body 1 may be extracted from the mandrel 10 and transferred to the mandrel 10 of the overcoat station 17 to secure the time for lowering the temperature of the can 1.

A discharge station 21 is provided on the front side of the overcoat station 17 in the turning direction of the mandrel 10. This discharge station 2
In 1, the can body 2 fitted to the mandrel 10 is extracted from the mandrel 10 by using a discharge means such as air, transferred to a conveyor (not shown), and conveyed to the next radiation irradiation step 22. Has become.

The radiation irradiation step 22 is performed at a front position away from the overcoat station 17 so as to secure a time (about 10 to 20 seconds) for the overcoat paint to flow into the recess of the film step portion 4 after application. It is provided.

In this radiation irradiating step 22, radiation lamps and the like are arranged over a predetermined range on both sides of the conveying path for supporting and conveying the can body 1 by a rotating pin or the like.
While the two-piece can 1 is rotated several times, the overcoat paint applied on the outer peripheral surface of the film of the two-piece can 1 is cured to form a uniform overcoat layer 3 on the entire peripheral surface of the can body. Here, as the radiation irradiation device, a device that radiates an electron beam, such as X-rays, gamma rays, beta rays or ultraviolet rays is used, but it is economically easily cured to about 200.
It is preferable to use one that radiates ultraviolet rays in the wavelength range of to 450 nm.

On the front side of the radiation irradiation step 22, the film-adhered two-piece can body 1 supported by the carrying means is pulled out from the pin, and the two-piece can body 1 is carried by a predetermined carrying means (not shown). It is designed to be transported to the subsequent process where the next inner surface coating, neck-in processing and flange processing are performed. Further, when it is necessary to heat and cure the adhesive after the film attaching step, an adhesive curing step 23 needs to be provided between the radiation irradiation step 22 and the subsequent step. It is heated and cured at the same time by utilizing the paint baking process of the inner surface coating process.

Next, the method of the present invention using the above apparatus will be described in detail. The metal can body 1 fitted and held on the outer periphery of the mandrel 10 is formed by drawing an aluminum disc and ironing it to form a bottom. It is a two-piece can 1 configured as an attached cylinder, and is not subjected to neck-in processing or flange processing. The two-piece can 1 is washed and then dried. Then, the two-piece can 1 is sent to the supply station 11 by a predetermined conveying means, and is delivered to the mandrel 10 there. That is, the mandrel 10 rotating on the circumference of a predetermined radius is attached to the supply station 1
At 1, the two-piece can 1 is fitted, and the mandrel 10 holds the two-piece can 1 in that state. Then, the two-piece can 1 is rotated together with the mandrel 10 on the circumference of a predetermined radius and rotated, and is subjected to high-frequency induction heating while passing the front side of the heating device 12 adjacent to the supply station 11. , The surface temperature of the can body is about 15
The temperature is raised to 0 ° C.

On the other hand, the decorative film 2 is provided with a printing layer 2b on one surface of the thermoplastic resin film 2a, with a range slightly longer than the circumferential length of the can body surface of the two-piece can body 1 as one section, and the printing thereof. The adhesive layer 2c is provided on the upper side of the layer 2b. This decorative film 2 is a two-piece can body 1.
Are cut into sections that are slightly longer than the perimeter of the can body surface and are adsorbed to the sticking roll 14 in the temporary bonding station 13. The cut decorative films 2 are adsorbed and held on the outer peripheral surface of the sticking roll 14 at the same intervals as the mandrel 10 and with the adhesive layer 2c on the outside. Further, the sticking roll 14 is the mandrel 10
Of the two-piece can body 1. As an example, the decorative film 2 is rotated at a high speed of 100 m / min so as to be supplied.

Therefore, when the two-piece can body 1 heated and heated by the heating device 12 reaches the temporary bonding station 13, the decorative film 2 is pressed against the can body surface by the bonding roll 14 and bonded by the bonding layer 2c. Attached. The pressing force is a linear pressure of 30 kgf / cm. The two-piece can body 1 rotates together with the mandrel 10, and the decorative film 2 is attached to the entire outer circumference of the can body surface without entraining air, and both ends thereof are overlapped.

The two-piece can 1 to which the decorative film 2 is temporarily adhered in this manner is held by the mandrel 10 and sent to the main adhering station 15. Since the main bonding station 15 is provided close to the temporary bonding station 13, the two-piece can 1 is sent to the main bonding station 15 without cooling. That is, the temperature of the two-piece can 1 is maintained at a temperature at which the adhesive does not solidify. In the main bonding station 15, a pressure roll 16 rotating at a peripheral speed corresponding to the turning speed and the rotation speed of the two-piece can body 1 is pressed against the outer surface of the two-piece can body 1, and the pressing force is linear pressure as an example. 60
It is kgf / cm.

Therefore, the decorative film 2 is re-pressed in a state where the adhesive is not solidified, and since the pressing force is large, the adhesive layer 2c protrudes into the stepped void portion 7 caused by the overlapping of the films and is fused with each other. . The situation is shown in FIG. 6, and inside the end portions of the decorative films 2 which are temporarily adhered and overlap each other, a step gap portion 7 corresponding to the thickness of the decorative film 2 is formed. Is further pressed by the pressure roll 16, the adhesive layer 2c
Extends into the stepped void portion 7 and fills this gap.

After being pressed by the pressure roll 16, the two-piece can body 1 is sent to the overcoat station 17, contacts the applicator roll 19 of the overcoater 18, and rotates on the outer peripheral surface of the can body at the same peripheral speed. Overcoat paint is applied to.

The two-piece can 1 thus overcoated on the decorative film 2 has the mandrel 10
Discharge station 2 on the circumference of a predetermined radius together with
It moves to 1 and moves from the mandrel 10 to the transport conveyor, and from the transport conveyor to, for example, a pin chain, which is irradiated with radiation (ultraviolet rays) while passing through the radiation irradiator and overcoated. The layer 3 is hardened. Note that the overcoated paint flows so as to fill the step 4 of the film overlapping portion 6 while being conveyed to the radiation irradiation device, and forms a predetermined inclined surface 5.

The two-piece can body 1 to which the decorative thermoplastic resin film 2 is attached in this manner is, after the adhesive curing step, extracted from the pin chain and conveyed to the subsequent step, as shown in FIG. The inner surface of the two-piece can body 1 is coated by a known method, and the opening end is subjected to neck-in processing or flange processing by a known method to manufacture a film-attached two-piece can body 1 '.

Next, examples of the present invention will be shown together with comparative examples.

[0064]

Example 1 A film sticking can was manufactured using a two-piece can body made of aluminum that was drawn and ironed. As shown in the schematic cross-sectional view of FIG. 2, the decorative film 2 is a printing layer having a thickness of 1 μm, which is gravure-printed with an ink made of urethane resin on one surface of a polyethylene terephthalate resin film 2a having a thickness of 16 μm. 2b, and a thickness of 6 μm composed of polyester resin, isocyanate resin, and amine resin (compounding ratio 94: 3: 3) thereon.
The thermosetting adhesive layer 2c was used.

As the overcoat paint, a paint composed of an ultraviolet curable resin is used. 30% by weight of a prepolymer is 70% by weight of an epoxy acrylate resin, 30% by weight of a triacrylate is a photopolymerizable monomer, and a photopolymerization initiator. 5 to 7% by weight of benzophenone and 1 to 2% by weight of silicon as a lubricant are uniformly mixed, and Ford cup No. 4, 25 ~ 60 seconds for 90 ~ 90 (200 ~ 350c
In p), the viscosity was adjusted. In the overcoat station 17, the overcoat paint was applied to the entire outer circumference of the decorative film by the overcoater 18. After the application, the overcoat paint applied on the film overlapping portion 6 is, as shown in FIG. 3, a film step portion formed at the tip of the film lower than the overlapping portion 6 due to the fluidity of the paint in a wet state. The surface of the overcoat coating film flowing in a large amount into No. 4 and covering the step portion 4 formed a gentle slope 5 without following the cross-sectional shape of the step portion 4. Here, the step portion 4 is a step corresponding to the thickness of the film, which is generated by stacking the leading ends of the films.

In the radiation irradiation step, the wavelength of 200 to
The overcoat paint was cured by irradiating it with UV light of 450 nm for 0.5 seconds. Overcoat layer 3 after curing
Since the solvent was solvent-free, the loss of the paint due to the hardening of the paint was extremely small, and as shown in FIG. 4, a gentle slope 5 was formed which substantially maintained the gentle slope 5 in the wet state.
The overcoat coating thickness OBD on the overlapping portion is 2
μm, overcoat film thickness OBS on the general surface is 7μ
m.

The height difference T2 in the film overlapping portion 6 of the overcoat layer 3, that is, the outer surface of the overcoat layer on the film overlapping portion 6 and the surface of the overcoat layer other than the film overlapping portion The step difference between the film thickness of the film 2a and the total thickness T1 of the printing layer 2b and the adhesive layer 2c was about 78%.

In this embodiment, the well-known epoxy-phenolic paint is spray-coated on the inner surface and the bottom surface of the two-piece can 1 sent out from the radiation irradiation step 22, then the coating is dried and the adhesive is heated. Heated at 220 ° C. for 60 seconds for curing. After that, neck-in processing and flange processing were performed on the open end of the two-piece can body 1 by a known method.

Two-piece can body 1 thus obtained
As a result of visual inspection, no wrinkles or cracks were found in the neck-in processed portion, particularly in the neck processed portion where three or more steps were die-neck processed, and the decorative film 2 was not peeled at all. Further, the two-piece can body 1 is filled with coffee liquid by a conventional method and sealed,
When retort sterilization treatment was performed at 125 ° C for 30 minutes,
No bleaching of the blister or the film 2 occurred, and it was possible to obtain a beautiful film-adhered can whose appearance was protected by the transparent film of the printing layer and the overcoat layer.

[0070]

Example 2 As an adhesive composed of an electron beam curable resin,
A mixture of 2 to 20 parts by weight of a polyester oligomer having an unsaturated double bond and 0.5 to 250 PHR (parts by weight with respect to 100 parts by weight of resin) of a polyester resin was used per 100 parts by weight of the polyester resin. Further, the overcoat paint made of an electron beam curable resin is 70% by weight of an epoxy acrylate resin as a photopolymerizable prepolymer,
A diacrylate resin or a monofunctional acrylate resin as a photopolymerizable monomer was added in an amount of 30% by weight, and a silicone wax as a lubricant was added in an amount of 1 to 2% by weight. 4. The viscosity was adjusted to 60 to 90 seconds at 25 ° C.

The can body and the decorative film attached to the outer surface thereof were the same as in Example 1 above. After coating the overcoat paint prepared as described above on the body surface of the can with the thermoplastic resin film attached, the adhesive layer and overcoat layer are cured by irradiating with an electron beam of 3 Mrad when passing through the electron beam irradiation device. Let Then, a known epoxy-phenolic paint was spray-coated on the inner surface and the bottom surface of the two-piece can body, and the paint was dried at 220 ° C. for 60 seconds. After that, neck-in processing and flange processing were performed on the open end of the two-piece can body by a known method.

The heating of the two-piece can, the temporary adhering of the decorative film and the main adhering in this embodiment were carried out in the same manner as in the above-mentioned Embodiment 1.

Also in this example, no wrinkles or cracks were found at the necked portion, and the decorative film was not peeled off at all. Further, when the retort sterilization treatment was carried out under the same conditions as in Example 1, no blister or whitening occurred, and a beautiful film sticking can could be obtained.

[0074]

[Example 3] A spray coating with an epoxy-phenolic paint was applied to the inner surface of the can and the bottom surface of the can, and a treatment of drying at 220 ° C for 60 seconds was performed before the decoration film was attached (heating after attachment of the film). Is omitted). Other conditions were the same as in the case of Example 2 described above, but when a film-coated can was manufactured, the same results as in Example 2 were obtained.

[0075]

Comparative Example 1 This is an example in which the viscosity condition of the overcoat paint is out of the range of the present invention. A decorative film sticking can was prepared under the same conditions as in Example 1 except that the overcoat paint comprising an ultraviolet curable resin contained 20% by weight of triacrylate as a photopolymerizable monomer. The viscosity of the overcoat paint in this case is Ford Cup N
o. It was 100 seconds or longer at 4, 25 ° C. Ie 35
It showed a viscosity of more than 0 cp. This overcoat paint is applied to the outer surface of the can body, that is, the decoration film is applied to the outer surface of the can body which is pasted with the both ends of the film overlapped, and is irradiated with ultraviolet rays in the ultraviolet irradiation step to cure the overcoat paint, Due to the poor fluidity of the paint, the film thickness of the film overlapping part does not become too thin before the UV irradiation, and the height difference T2 and film thickness in the film overlapping part of the overcoat layer The value of the ratio T2 / T1 was 0.9 to 0.95. The height difference T2 of the overcoat layer was as large as about 21 μm. Furthermore, the overcoat layer in the step portion is not leveled, and a steep inclined surface where stress concentration is likely to occur is formed. When neck-in processing was performed on the open end of the can body, 30-40% of wrinkles were generated in the neck processed portion.

[0076]

Comparative Example 2 This is an example in which a thermosetting resin is used in the overcoat paint. After adhering the decorative film to the two-piece can body in the same manner as in Example 1, a thermosetting resin was used as the overcoat paint, and the paint was heated at 190 ° C. for 5 seconds to be dried, whereby the adhesive melted. As a result, the decorative film in the upper layer was heat-shrinked, the dimensions of the pattern were changed, and wrinkles were generated in the decorative film. The composition of the adhesive is the same as that shown in Example 1.

Therefore, the heating and drying temperature of the overcoat paint was lowered, and it was heated at 130 ° C. for 5 seconds to be dried.
When the retort sterilization treatment was performed at 125 ° C. for 30 minutes, whitening of the overcoat layer occurred. Further, when the inner surface paint was baked, when the cans contacted each other in the oven, the overcoat layer was insufficiently cured, so that the coating film was softened to cause tackiness and blocking occurred.

[0078]

[Comparative Example 3] This is an example in which a film having an overcoat layer formed in advance was attached. An overcoat paint containing 80% of an epoxy resin, 20% of a melamine resin, about 3% of silicon as a slip agent, and 0.5 to 1% of a wax was previously applied to the surface (the surface opposite to the printing layer) and dried. The decorative film was attached to the outer surface of the same metal can as the can used in Example 1 under the same conditions as in Example 1 to produce a film-adhered can. However, in this film-attached can, the upper layer film was peeled off due to defective adhesion of the film overlapping portion during neck-in processing.

The present invention can be applied to metal cans other than two-piece cans.
The same operation can be performed using a device other than the device shown in FIG.

[0080]

As described above, according to the present invention, an overcoat layer containing a lubricant such as silicone or wax is formed on the upper surface of the lower film at both ends of the film, that is, the surface of the upper film in contact with the adhesive layer. Since it is not present, the adhesion between the films will be good. Further, since an overcoat layer made of a radiation curable resin is formed on the entire outer peripheral surface of the film of the can after the film is attached, the film hardness of the surface of the can body is high and scratch resistant and glossy. It is possible to prevent the film from being scratched or peeled off due to rubbing between the cans or the guide during transportation.

Further, according to the present invention, since the overcoat paint is made of a radiation curable resin, it is not necessary to heat it during curing, the deformation of the decorative film due to heat shrinkage can be prevented, and the film sticking excellent in appearance can be applied. It can be a can.

Further, according to the present invention, the outer surface of the film of the printed thermoplastic resin film-adhered can has the steps of the overcoat layer leveled at the film step portion, so that the outer circumference of the can is apparently seen. It looks like a uniform surface without irregularities. Also, because it is covered with an overcoat layer, when applying neck-in processing (especially die-neck processing) to the open end of the film sticking can, it is possible to prevent stress concentration of compressive force acting in the circumferential direction on the neck part. , Wrinkles at the neck and opening of the film end are prevented. Further, it is possible to prevent rust and floating of the film in the film joining portion which is likely to occur in the sterilization process, and the step portion on the upper layer side is also finished neatly, so that the appearance quality can be improved.

When the electron beam curable overcoat paint is applied to the can body surface of the film sticking can, by using the electron beam curable resin as the adhesive, the curing step by heating the adhesive is omitted. The radiation (electron beam) irradiation for curing the overcoat paint can accelerate the curing of the adhesive at the same time, and as a result, the curing of the adhesive can be performed together in the irradiation step.

Further, according to the present invention, since the ink does not exist in the lower layer of the overcoat paint, the film thickness of the overcoat layer can be reduced, which is economical.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a metal can body targeted by the present invention.

FIG. 2 is a schematic sectional view of a decorative film used in the present invention.

FIG. 3 is a schematic sectional view of a film overlapping portion in the film sticking can according to the present invention.

FIG. 4 is a view showing respective dimensions at the film overlapping portion.

FIG. 5 is a process chart for explaining an example of the method of the present invention.

FIG. 6 is a schematic cross-sectional view showing a state before and after pressing the film overlapping portion.

FIG. 7 is a process chart for explaining another example of the method of the present invention.

FIG. 8 is an overall schematic diagram showing a decorative film sticking device that can be used in the present invention.

FIG. 9 is an overall schematic diagram showing another example of the decorative film sticking device.

[Explanation of symbols]

1 ... Two-piece can (can body), 2 ... Decorative film,
2a ... film, 2b ... printing layer, 2c ... adhesive layer,
3 ... Overcoat layer, 5 ... Inclined surface, 6 ... Film overlapping portion, 7 ... Step portion, 12 ... Heating device, 1
3 ... Temporary bonding station, 15 ... Main bonding station, 17 ... Overcoat station, 22 ... Radiation irradiation step.

Claims (5)

[Claims] 1. A thermoplastic resin film for decoration, having a printing layer and an adhesive layer formed on one surface thereof, is superposed on both ends of the outer can body surface of a metal plate can body through the adhesive layer. In the film sticking can body stuck in a state, the radiation-cured overcoat layer is formed on the entire outer peripheral side of the stuck decorative thermoplastic resin film, and the overcoat layer is Formed in a film thickness thinner than the other portions on the film overlapping portion, the step of the overcoat layer due to the film overlapping is leveled, and the overcoat layer surface covering the film step portion,
A film-attached can body, characterized in that it is formed into a gentle slope in the circumferential direction of the can body surface. 2. The height difference between the outer surface of the overcoat layer at the film overlapping portion and the outer surface of the overcoat layer on the general surface other than the film overlapping portion causes the printing layer and the adhesive layer to be different from each other. The film sticking can body according to claim 1, wherein the thickness of the decorative thermoplastic resin film is 80% or less. 3. The film sticking can body according to claim 1 or 2, wherein the overcoat layer and the adhesive are made of an electron beam curable resin. 4. A decorative thermoplastic resin film having a printed layer and an adhesive layer made of a thermosetting resin formed on one surface of the outer can body surface of a metal can body is attached via the adhesive layer. After wearing, in the method for producing a film-attached can body that performs neck-in processing and flange processing on the opening end of the can body, a heating step of heating the can body, and the decorative thermoplastic resin film in advance. A film cutting step of cutting the can body longer than the perimeter, and the cut decorative thermoplastic resin film on the can body surface of the heated can body via the adhesive, A film adhering step in which both ends of the plastic resin film are heat-adhered so that they overlap each other, and an overcoat made of a solvent-free and fluid UV curable resin on the outer surface side of the decorative thermoplastic resin film after adhering An overcoat coating step of applying a coating material, an ultraviolet irradiation step of irradiating the outer surface side of the can body with ultraviolet rays to cure the overcoat coating material to form an overcoat layer, and an adhesive for heating and curing the adhesive agent. A method of manufacturing a film sticking can body, which comprises a curing step. 5. A decorative thermoplastic resin film having a printing layer and an adhesive layer made of an electron beam curable resin formed on one surface on the outer can body surface of a metal can body, with the adhesive layer interposed therebetween. After sticking, the method for producing a film-attached can in which neck-in processing and flange processing are performed on the opening end of the can body, a heating step of heating the can body, and the decorative thermoplastic resin film, A film cutting step of cutting the can body longer than the perimeter of the can body, and the cut decorative thermoplastic resin film on the can body surface of the heated can body via the adhesive and for decoration. Thermoplastic resin film is heat-bonded so that both ends overlap each other, and the outer surface of the decorative thermoplastic resin film after bonding is made of solvent-free and fluid electron beam curable resin. Overcoat paint And an electron beam irradiation step of irradiating an electron beam from the outer surface side of the can body to cure the overcoat paint to form an overcoat layer and simultaneously cure the adhesive. A method of manufacturing a film sticking can body, which comprises: