JP4671799B2 - Laminated film and cylindrical label - Google Patents

Description

  The present invention relates to a laminated film in which two or more layers are laminated and bonded via an adhesive, and a cylindrical label using the laminated film.

In general, food-filled containers filled with coffee, black tea, green tea, etc. are often heated or cooled to eat the filling. If the container thus heated or cooled is held by hand, the temperature of the filling is directly transmitted to the hand, and therefore, a label having heat insulation is used as a cylindrical label attached to the container.
For example, Japanese Patent Application Laid-Open No. 2005-70739 discloses a heat-shrinkable cylindrical label made of a laminated film in which a nonwoven fabric is laminated on the back surface of a heat-shrinkable film as a cylindrical label to be shrink-mounted on a container.

Such a heat-shrinkable cylindrical label is formed into a cylindrical shape by using a laminated film in which a nonwoven fabric is laminated on a heat-shrinkable film, with the nonwoven fabric as the back side of the label.
When a cylindrical label is formed using a laminated film in which the nonwoven fabric is laminated, the laminated film is generally laminated so that one side edge of the nonwoven fabric is located inside the one side edge of the heat-shrinkable film. The reason is as follows.
A heat-shrinkable cylindrical label rolls a film into a cylinder, superimposes the back surface of one side of the film on the surface of the other side, and bonds the overlapped part using a solvent (or adhesive). (This overlapping adhesion portion is generally referred to as a center seal portion). In this regard, when a laminated film in which a nonwoven fabric is laminated on the entire surface of the heat-shrinkable film is used, when the back surface of one side portion of the laminated film is superimposed on the surface of the other side portion, Therefore, it is extremely difficult to bond them well from the viewpoint of the appearance and adhesive strength of the center seal portion.
Accordingly, a laminated film in which one side edge of the nonwoven fabric is laminated so as to be located inside the one side edge of the heat-shrinkable film, and a film exposed portion having no nonwoven fabric is formed on one side portion of the heat-shrinkable film. By using it, the film surfaces can be superposed and bonded.

By the way, it is also possible to produce a heat-shrinkable cylindrical label by forming the laminated film in which the nonwoven fabric is laminated into a cylindrical shape with the nonwoven fabric being on the label surface side.
Thus, even when the nonwoven fabric is formed into a cylindrical shape with the label surface side, for the same reason as described above, one side edge of the nonwoven fabric is positioned inside the one side edge of the heat-shrinkable film. A laminated film laminated on is used.

However, when one side edge of the nonwoven fabric is laminated so as to be located inside the one side edge of the heat-shrinkable film in this way, one side edge of the nonwoven fabric does not adhere securely to the laminated surface of the heat-shrinkable film. There is a risk that one side edge of the nonwoven fabric may be rolled. When one side edge of the nonwoven fabric is curled in this way, the cylindrical label having the nonwoven fabric as the surface side has poor appearance and the commercial value as the label is lowered.
In this respect, if the adhesive for laminating and bonding the heat-shrinkable film and the nonwoven fabric is applied up to one side edge of the nonwoven fabric, the above-mentioned problem (one side edge curl) can be prevented.
However, when the adhesive is applied up to one side edge of the nonwoven fabric, the adhesive may protrude outside the one side edge of the nonwoven fabric, and blocking occurs when the laminated film is wound up in a roll shape. There is a problem.
The above-mentioned problems are not limited to the case of laminating non-woven fabrics. That is, the problems occur in laminated films in which two or more films are laminated and adhered with their side edge positions shifted regardless of the material.

JP-A-2005-70739

  Therefore, in the present invention, in the laminated film in which the position of the side edge is shifted and the film is laminated and adhered with an adhesive, the side edge of one film is securely adhered to the laminated surface of the other film, and the winding is performed. It is an object of the present invention to provide a laminated film capable of preventing the occurrence of blocking at the time of taking. Moreover, this invention makes it the 2nd subject to provide the cylindrical label formed by shape | molding this laminated | multilayer film in a cylinder shape.

In the first means of the present invention, the second film is laminated and bonded to one surface of the first film via an adhesive layer, and the first film, the adhesive layer, and the second film extend in the longitudinal direction. Each having a side edge and another side edge, the one side edge of the second film being positioned inside the one side edge of the first film, and the one side edge of the adhesive layer being at least one side edge of the second film In the laminated film provided up to , the non-adhesive treatment for the adhesive of the adhesive layer is performed on the other surface of the first film corresponding to the longitudinal belt-shaped region including at least one side edge of the adhesive layer. A laminated film is provided.

In such a laminated film, since the adhesive layer is provided at least on one side edge of the second film, the second film can be bonded to the first film at the one side edge. Therefore, it is possible to provide a laminated film in which one side edge of the second film is not likely to be rolled up.
The laminated film is usually wound up in a roll and used for storage and transportation. Thus, when it rolls up in roll shape, the one surface side and other surface side of a laminated | multilayer film contact | connect, ie, the surface side of a 2nd film, and the other surface side ( non-laminate surface side ) of a 1st film contact | connect. In this respect, the laminated film of the present invention is a non-laminated surface of the first film (the other surface of the first film that is the surface opposite to the one surface of the first film on which the second film is laminated). The region corresponding to the longitudinal belt-like region including at least one side edge of the adhesive layer is subjected to a non-adhesion treatment for the adhesive of the adhesive layer. With this configuration, the non-adhesive treatment of the first film overlaps the adhesive that may come out from the one side edge of the second film when wound into a roll. Accordingly, it is possible to provide a laminated film that is less likely to cause blocking when wound into a roll.

In a preferred aspect of the present invention, the one side edge of the adhesive layer is provided outside the one side edge of the second film so that one side edge of the second film and one side edge of the first film are provided. Provided is the above laminated film in which an adhesive layer exposed portion is formed therebetween, and a non-adhesive treatment is applied to at least a region corresponding to the adhesive layer exposed portion of the other surface of the first film .
In the laminated film, since the adhesive layer is provided so as to protrude outward from one side edge of the second film, the one side edge of the second film can be reliably bonded to the first film. Moreover, since the non-adhesion process is performed to the area | region corresponding to an adhesive bond layer exposure part, generation | occurrence | production of blocking can be prevented when a laminated | multilayer film is wound up in roll shape.

  Moreover, in the preferable aspect of this invention, the said adhesive bond layer exposed part provides the said laminated | multilayer film currently formed thinly. In such a laminated film, since the exposed portion of the adhesive layer is formed in a thin shape, the amount of adhesive applied in this portion is small, and therefore when the film is rolled up, blocking of the laminated film occurs. It can be surely prevented.

  Furthermore, the preferable aspect of this invention provides the said laminated | multilayer film in which a 1st film contains the synthetic resin film which has heat shrinkability, and the said 2nd film contains a nonwoven fabric. Such a laminated film becomes a heat-shrinkable laminated film, and a heat-shrinkable cylindrical label provided with a nonwoven fabric can be formed by forming this into a tubular shape.

  Moreover, the 2nd means of this invention provides the cylindrical label formed by shape | molding any one of the said laminated | multilayer film in a cylinder shape by making the 2nd film into the label surface side.

The laminated film according to the present invention can prevent the occurrence of blocking during winding while adhering one side edge of the second film to the laminated surface of the first film.
In such a laminated film, there is no possibility that one side edge of the second film is rolled up.
Therefore, a cylindrical label formed by forming this laminated film into a cylindrical shape with the second film as the label surface side has no risk of the second film rolling up and exhibits a beautiful appearance.

Hereinafter, the present invention will be specifically described with reference to the drawings.
In FIG. 1, reference numeral 1 denotes a heat-shrinkable laminated film in which a second film 3 is laminated and adhered to one surface 2 a of a first film 2 having heat-shrinkability via an adhesive layer 5.
Specifically, this heat-shrinkable laminated film 1 has an adhesive layer 5 on the inner side of the one side edge 21 of the first film 2 (the inner side means the center side in the width direction of the laminated film 1. The same applies hereinafter). The one side edge 51 is positioned, and the one side edge 31 of the second film 3 is positioned inside the one side edge 51 of the adhesive layer 5, and the first film 2 and the first film 2 are inserted through the adhesive layer 5. Two films 3 are laminated and adhered.

Therefore, the adhesive layer exposed portion 53 where the adhesive layer 5 is exposed is disposed between the one side edge 21 of the first film 2 and the one side edge 31 of the second film 3 at one side portion of the laminated film 1. Is formed in a longitudinal belt shape.
Further, in one side portion of the laminated film 1, the first film exposed portion 23 where the first film 2 is exposed is disposed between the one side edge 21 of the first film 2 and the one side edge 51 of the adhesive layer 5. Is formed in a longitudinal belt shape.
The second film 3 is not laminated on the adhesive layer exposed portion 53 and the first film exposed portion 23, and the first film exposed portion 23 is the center seal of the heat-shrinkable cylindrical label 10 described later. One side overlap margin for forming the portion 9 is formed.
The width W1 of the adhesive layer exposed portion 53 (the interval W1 between the one side edge 31 of the second film 3 and the one side edge 51 of the adhesive layer 5) is not particularly limited, and is, for example, about 1 to 4 mm.
The width W2 of the first film exposed portion 23 (the interval W2 between the one side edge 21 of the first film 2 and the one side edge 51 of the adhesive layer 5) is, for example, about 3 to 6 mm.
Therefore, the width of the one side overlap margin is formed to be about 3 to 6 mm, for example.
Note that the other side edges of the first film 2, the adhesive layer 5, and the second film 3 are aligned at the other side edge of the laminated film 1 as illustrated.

On the other surface 2b of the first film 2 (non-laminated surface of the second film 3), a design printing layer 6 is provided in which a predetermined design display such as a product name, a picture, or an explanatory note is printed by a known printing method. ing. This design print layer 6 is the other surface 2b of the first film 2 and has a predetermined width from the other side edge 22 (generally wider than the one side overlap allowance or the same width as the one side overlap allowance). ) Are provided.
The design print layer 6 is preferably provided on the other surface 2 b of the first film 2, but can also be provided on one surface 2 a of the first film 2 (lamination surface of the second film 3). As described above, when the design print layer 6 is provided on the one surface 2 a of the first film 2, a non-transparent material can be used as the first film 2.
It is also possible to provide the design print layer 6 on the surface of the second film 3.

  Furthermore, a non-adhesive portion 7 is provided on the other surface 2 b of the first film 2 in order to make it non-adherent to the adhesive of the adhesive layer 5. This non-adhesion part 7 is overlapped with the design print layer 6 provided on the other surface 2b of the first film 2 in a predetermined range of the other surface 2b of the first film 2 (of the other surface 2b of the first film 2). In a range excluding a predetermined width from the other side edge 22 of the first film 2, the non-adhesive treatment is performed. The portion where the non-adhesive portion 7 (and the design print layer 6) is not provided constitutes another side overlap margin for forming the center seal portion 9 of the cylindrical label 10. Further, at one side edge of the laminated film 1, one side edge of each of the first film 2, the design printing layer 6, and the non-adhesive portion 7 is aligned as illustrated.

  As non-adhesion treatment, for example, a coating liquid containing a release agent such as a silicone resin (for example, gravure ink containing silicone) or an additive capable of improving releasability such as wax, lubricant, or silicone oil is mixed. For example, a coating solution having excellent peelability with respect to the adhesive, such as a coating solution, may be used. When a urethane-based adhesive is used as the adhesive layer 5, a coating liquid containing a polyamide-based resin (for example, a polyamide nitrified cotton-based transparent ink) is used as the coating liquid used for the non-bonding process. It can also be used. Since the coating method of these coating liquids is simple, it is preferably performed by a known printing method (for example, a printing method such as gravure printing or flexographic printing). Since the formation of the design printing layer 6 and the non-adhesion treatment (formation of the non-adhesive portion 7) can be performed in one printing process (the same printing machine), it is more preferable.

  The heat-shrinkable laminated film 1 is formed into a cylindrical shape so that the second film 3 is on the label surface side, and the one side surface (one side overlap margin) of the first film 2 is the other side of the first film 2 The heat-shrinkable cylindrical label 10 of the present invention is configured by overlapping the part back surface (overlap part on the other side) and bonding the overlapped part with a solvent or an adhesive to form the center seal part 9. (See FIG. 2 and FIG. 3).

  The 1st film 2 consists of a colorless and transparent heat-shrinkable film which can see through the design printing layer 6, and it does not specifically limit about the material. For example, one type selected from polyester resins such as polyethylene terephthalate, olefin resins such as polypropylene, styrene resins such as styrene-butadiene copolymers, cyclic olefin resins, and thermoplastic resins such as vinyl chloride resins, Or the heat-shrinkable film which consists of 2 or more types of mixtures etc. is illustrated. Moreover, you may be comprised by the laminated body which laminated | stacked two or more types of different films. In particular, when a film that does not substantially heat shrink is used as the second film 3, the first film 2 is made of a polyester-based resin film having a strong shrinkage force or a laminate thereof in order to pull the second film 3 to shrink. It is preferable to use it. A heat-shrinkable film can be obtained by forming a film by a known production method and stretching the film. The stretching treatment is usually performed at a temperature of about 70 to 110 ° C., and is stretched by 2.0 to 8.0 times, preferably about 3.0 to 7.0 times in the width direction (circumferential direction in the case of a cylindrical label). Is done. Furthermore, the stretching process may be performed at a low magnification of, for example, 1.5 times or less in the longitudinal direction (the direction orthogonal to the width direction, which is the longitudinal direction when a cylindrical label is used). The obtained film becomes a uniaxially stretched film or a biaxially stretched film slightly stretched in a direction orthogonal to the main stretch direction. The thickness of the first film 2 is preferably about 20 to 100 μm, more preferably about 30 to 80 μm.

The first film 2 has a thermal shrinkage rate in the width direction of, for example, about 30% or more, preferably about 40% or more, particularly preferably 50% or more when immersed in warm water of 90 ° C. for 10 seconds. Things are used. In addition, the heat shrinkage rate in the vertical direction is -3 to 10%, preferably about -1 to 6%.
However, heat shrinkage rate (%) = [{(original length in width direction (or longitudinal direction)) − (length after immersion in width direction (or longitudinal direction))} / (width direction (or longitudinal direction) ) Original length)] × 100.

Furthermore, the first film 2 is preferably a heat-shrinkable film having a shrinkage stress in the width direction of 3 MPa or more, more preferably 5 MPa or more when immersed in warm water at 90 ° C. By using a heat-shrinkable film having such a shrinkage stress, when the heat-shrinkable cylindrical label 10 is formed, the label 10 can be sufficiently adhered to a mounted body such as a container.
The shrinkage stress was cut into a rectangular shape with a width of 150 mm and a length of 15 mm, and both ends of the film piece in the width direction were used as chucks for a stress measuring instrument (manufactured by Shimadzu Corporation, trade name: Autograph). It is held (distance between chucks: 100 mm), immersed in warm water at 90 ° C. for 10 seconds, and the maximum contraction stress (MPa) generated during that time.

  The adhesive used for the adhesive layer 5 is not particularly limited as long as it can adhere the first film 2 and the second film 3, and examples thereof include a known dry laminate adhesive and wet laminate adhesive. Examples of the dry laminate adhesive include solvent-based adhesives such as acrylic, urethane, polyester, polyether, vinyl acetate, vinyl chloride, and rubber, or two-component adhesives. The thickness of the adhesive layer 5 is formed to about 2 to 10 μm, for example. Further, the adhesive layer 5 is provided by applying the adhesive in a solid coating shape, and if the first and second films 2 and 3 can be integrated, the adhesive layer 5 is applied in a net shape or the like. It is also possible to provide them.

  Next, the 2nd film 3 is not specifically limited, Various conventionally well-known films can be used, for example, a nonwoven fabric, a foamed resin sheet, Japanese paper, a synthetic resin film etc. can be used (however, this specification) "Sheet" in the book is synonymous with "film"). Moreover, the 2nd film 3 may be comprised from the laminated body of the same kind or different kind of film. Especially, since it has heat insulation, as the 2nd film 3, it is preferable to use what contains heat insulation sheets, such as a nonwoven fabric, a foamed resin sheet, and Japanese paper. Further, when forming the heat-shrinkable cylindrical label 10 with the second film 3 as the label surface side, it is preferable to use a non-woven fabric or Japanese paper as the second film 3 because it can give a high-class feeling.

The non-woven fabric is not particularly limited, and non-woven fabric or pulp made of a fiber such as polyester, polypropylene, polyethylene, rayon paper, nylon, cupra, etc. by a bonding method, a needle punch method, a spun bond method, a melt blow method, etc. A Japanese paper-like non-woven fabric produced by a paper-making method or the like can be used. As the fibers constituting the nonwoven fabric, solid fibers, hollow fibers, or mixed fibers thereof can be used, and it is preferable to use hollow fibers or mixed fibers thereof because they are more excellent in heat insulation. Denier is preferably about 2-5d. The fiber length is preferably a long-fiber non-woven fabric sheet in terms of strength due to a three-dimensional network structure formed by entanglement of fibers and the handleability of the sheet, and a short-fiber non-woven fabric is preferable in terms of sheet cutting suitability. For example, it is preferable to use a nonwoven fabric having a basis weight of about 10 to 50 g / m ² , preferably 15 to 30 g / m ² , and a thickness of about 80 to 200 μm. If the basis weight is too small, there is a risk of tearing when the first film 2 is laminated and bonded. On the other hand, if the basis weight is too large, the first film 2 may not sufficiently follow and shrink due to heat shrinkage. This is because the design printing provided on the first film 2 may not be visible through the nonwoven fabric. In addition, as a nonwoven fabric, what can be thermally shrunk at least in the width direction can also be used.
Specific examples of the nonwoven fabric include “Marix” manufactured by Unitika Ltd., “Bonden” manufactured by Toyobo Co., Ltd., “Ecule”, “Unicel” manufactured by Unicel Corporation. A colored nonwoven fabric can also be used.

  The foamed resin sheet is not particularly limited, and for example, polystyrene, polyethylene, polypropylene, polyurethane and the like can be used. Among them, it is preferable to use a polystyrene type because it has suitable foamability. As the styrene-based resin, in addition to a polymer composed of a general-purpose styrene monomer, a copolymer of styrene-butadiene, maleic anhydride, methacrylic acid, and the like with styrene can be used. The foaming method may be a known foaming method such as physical foaming or chemical foaming. Additives such as various fillers, colorants, plasticizers, and stabilizers can be appropriately added to these resins as necessary. The foamed resin sheet has a white color because it contains a large number of bubbles, but a white pigment such as titanium oxide may be added to improve the white density. The thickness of the foamed resin sheet is preferably about 80 to 300 μm, for example. In addition, it is preferable to use a foamed resin sheet that can be thermally shrunk in the width direction. However, the foamed resin sheet may not be thermally shrunk as long as it can shrink following the heat shrinking force of the first film 2.

Japanese paper can be made from natural bast long fibers such as cocoon, mitsumata, ganpi, etc., and hand-rolled with nellies. In the present invention, in addition to these koji, broad Japanese paper obtained by mechanically kneading various long fiber materials such as hemp, kenaf, rayon, wood pulp, and synthetic fiber is also included. Among them, it is preferable to use, for example, Yunlong paper. Japanese paper having a basis weight of about 9 to 25 g / m ² is used. If the basis weight is too small, there is a risk of tearing when laminating and adhering to the first film, while if the basis weight is too large, there is a risk that the first film will not sufficiently follow and shrink due to heat shrinkage. This is because the design print provided on one film may not be visible through Japanese paper.

  The synthetic resin film used as the second film 3 is not particularly limited, and for example, the heat-shrinkable film exemplified as the first film 2 can be used.

The heat-shrinkable laminated film 1 and the heat-shrinkable cylindrical label 10 can be manufactured, for example, by the following method. Hereinafter, a method for producing an even number of times (for example, two rows) of laminated films from the original film will be described in detail.
As shown in FIG. 4, the 1st film original fabric 200 of the predetermined width | variety which can obtain the laminated film 1 of 2 rows is prepared by cut | disconnecting to the cutting direction line X longitudinally. That is, the first film original fabric 200 is subjected to the respective lamination processes described later, and then cut in the longitudinal direction along the planned cutting line X at the substantially central portion in the width direction, whereby two rows of heat-shrinkable laminated films 1, 1 are obtained. Can be obtained.
The design printing layer except for a predetermined width (about twice the width of the other side overlap margin) in the center portion in the width direction across the planned cutting line X on the back surface (other surface) of the first original film 200 6 are provided in the left and right regions by gravure printing or the like. The design print layer 6 is printed with the display direction of the product name or the like displayed upward in the left region and displayed downward in the right region. That is, the display of the design print layer 6 is printed in the reverse direction in the adjacent area across the planned cutting line X.

  Next, a known printing method using a gravure roll plate or the like with a coating solution excellent in peelability with respect to the adhesive so as to be overcoated on the design printing layer 6 of the first film original fabric 200 Apply by. By this coating, the non-adhesive portion 7 is formed on the back surface of the first film original fabric 200.

Next, as shown in FIGS. 5A and 5B, the adhesive layer 5 is applied to the surface (one surface) of the first original film 200 by a known printing method or the like. This adhesive layer 5 removes a predetermined width (width W2 of the first film exposed portion 23) from both side edges 210, 210 of the first film original fabric 200, and applies the adhesive to the surface of the first film original fabric 200 as described above. Apply by printing method. Next, the first film original fabric 25 is guided to the solvent recovery zone via the transport roller so that the adhesive can be bonded.
Then, the second film original fabric 300 is pulled out from the second film original fabric roll separately formed to have a predetermined width (slightly narrower than the entire width of the adhesive layer 5), and both side edges 310, 310 are the adhesive layer 5. The second film original fabric 300 is bonded to the adhesive layer 5 (see FIG. 2C). And the 1st film original fabric 200 and the 2nd film original fabric 300 are adhere | attached through the adhesive bond layer 5 by pressing with a pressurizing roller.

  In addition, although the said lamination | stacking method uses the 2nd film original fabric 300 previously formed by the predetermined width, it is also possible to use the 2nd film original fabric 300 which is not formed previously by the predetermined width. Specifically, in the laminating step, the second film original 300 is slightly narrower than the width of the adhesive layer 5 immediately before the second film original 300 is bonded to the adhesive layer 5. The anti-300 is cut and removed in the longitudinal direction with a cutter, and bonded so that both side edges 310 of the cut second film original fabric 300 are inside the both side edges 51 of the adhesive layer 5. Thus, there is an advantage that it is easy to adjust the bonding position of the second film original fabric 300 by cutting immediately before the second film original fabric 300 is bonded. More specifically, a second film original fabric 300 having a predetermined width (slightly narrower than the adhesive layer 5) is prepared in advance as in the laminating step, and both side edges 310 of the adhesive layer 5 are prepared. It is also possible to bond them so that they are located inside the side edges 51 respectively. However, since the 2nd film original fabric 300 is elongate, it is easy to produce a blur in the width direction at the time of lamination, and in order to guide the 2nd film original fabric 300 previously cut by the predetermined width, and to stick on an exact position Needs to be adjusted frequently. In this respect, if the second film original fabric 300 is guided to the point just before the bonding point and bonded while being cut as in the above modification, both side edges 310, 310 of the second film original fabric 300 are immediately before bonding, Since it will be located inside the both side edges 51, 51 of the adhesive layer 5, respectively, it is preferable because the position adjustment can be simplified.

Next, by cutting the whole in the longitudinal direction along the planned cutting line X (however, for the purpose of width adjustment, a predetermined width is formed in the longitudinal direction from both side edges 210, 210 of the first film 200) The same two rows of laminated films 1 and 1 can be obtained. After the laminating step, the obtained laminated film 1 is wound up in a roll shape as shown in FIG.
In addition, since the printing direction is reversed about one laminated film 1 among the laminated films 1 produced simultaneously in two rows, the same laminated film wound up in the same printing direction by rewinding. A roll 11 is obtained.
In addition, in the said manufacturing method, although the method of producing 2 rows simultaneously was illustrated, for example, 4 rows can also be produced simultaneously. In the case where four rows are manufactured at the same time, a raw material having a width approximately twice as large as that of the first film original fabric 200 used in the two-row simultaneous manufacturing may be used.

The laminated film roll 11 is loaded into a center seal device. In the center seal device, the laminated film 1 is pulled out from the roll 11 and formed into a cylindrical shape so that the second film 3 is on the surface side, while a solvent or an adhesive is placed in the longitudinal direction at the other side overlap margin. The cylindrical label continuous body is produced by coating and attaching the overlap allowance to the one side overlap allowance. This cylindrical label continuous body is usually wound up in a roll shape.
Finally, this cylindrical label continuum roll is loaded into a shrink labeler. In this shrink labeler, the cylindrical label 10 is produced by cutting it in the width direction at a predetermined length position while feeding out the continuous cylindrical label body, and this is inserted into the body of the container. Then, the inserted container is guided to a shrink zone such as a shrink tunnel, and the cylindrical label 10 is thermally contracted to obtain a labeled container in which the cylindrical label 10 is mounted on the body of the container. .

Since the heat-shrinkable laminated film 1 is provided with the adhesive layer 5 for bonding the first film 2 and the second film 3 outside the one side edge 31 of the second film 3, One side edge 31 of the second film 3 is securely bonded. Therefore, there is no possibility that the one side edge 31 of the second film 3 laminated with the position shifted inward from the one side edge 21 of the first film 2 is rolled.
Further, when the heat-shrinkable laminated film 1 is wound up in a roll shape, as shown in FIG. 6 (b), on the other surface 2b side of the first film 2 of the laminated film 1 ′ of the first roll, 2 The surface side of the second film 3 of the laminated film 1 ″ of the winding is in contact. The laminated film 1 of the present invention is provided with a non-adhesive portion 7 on the outermost surface 2b of the first film 2. Therefore, when wound in a roll shape, the non-adhesive portion 7 of the first roll of laminated film 1 ′ faces the adhesive layer exposed portion 53 of the second roll of laminated film 1 ″. Can be blocked.
Note that the laminated film 1 may be wound with the first film 2 inside, or may be wound with the second film 3 inside.

  In addition, if a heat-shrinkable cylindrical label is produced using the laminated film 1 in which one side edge 31 of the second film 3 is not bonded to the first film 2, when the label is shrink-mounted on the container, etc. Due to the thermal contraction of the first film 2, the one side edge 31 of the second film 3 rolls up significantly. In this respect, the heat-shrinkable cylindrical label 10 can prevent such occurrence of bulging.

Next, another embodiment of the present invention will be described. Hereinafter, parts different from those of the above-described embodiments will be mainly described. For the same configuration, terms and drawing numbers are used in the specification and drawings, and the description thereof may be omitted.
Fig.7 (a) shows the laminated | multilayer film 1 in which the one side part of the adhesive bond layer 5 is formed in the taper shape which inclines downward gradually toward an outer side. Specifically, one side portion of the adhesive layer 5 is formed in a tapered shape that gradually slopes downward from the inside of the one side edge 31 of the second film 3 toward the outside of the one side edge 31. Therefore, the thickness of the adhesive layer exposed portion 53 is formed to be thinner than the thickness of the adhesive layer 5 in the central portion in the width direction.
In the laminated film 1 of such a modification, the adhesive layer exposed portion 53 is formed in a thin shape, so that the amount of adhesive per unit area in the adhesive layer exposed portion 53 is small. Therefore, when the laminated film 1 is rolled up, the thin adhesive layer exposed portion 53 and the non-adhered portion 7 provided on the first film 2 are in contact with each other, so that the laminated film roll 11 is reliably blocked. Can be prevented.

  FIG. 7B shows the laminated film 1 in which one side portion of the adhesive layer 5 is formed in a step shape. Specifically, one side portion of the adhesive layer 5 is thinner than the thickness of the adhesive layer 5 from the inside of the one side edge 31 of the second film 3 to the one side edge 51 of the adhesive layer 5. Is formed. Even in the laminated film 1 of such a modified example, the adhesive layer exposed portion 53 is formed in a thin shape, so that the amount of adhesive at that portion is small, and blocking of the laminated film roll 11 can be reliably prevented.

  FIG. 8A shows the laminated film 1 in which the one side edge 51 of the adhesive layer 5 is provided up to a position substantially coincident with the one side edge 21 of the first film 2. Specifically, in the laminated film 1 of this modification, the adhesive layer exposed portion 53 is provided from the one side edge 21 of the first film 2 to the one side edge 31 of the second film 3.

FIG. 8B shows the laminated film 1 provided so that one side edge 51 of the adhesive layer 5 substantially coincides with one side edge 31 of the second film 3. Such a laminated film 1 can also adhere one side edge 31 of the second film 3 to the first film 2 via the adhesive layer 5. Moreover, the adhesive protruded from the one side edge 31 of the 2nd film 3 by the pressure at the time of pressing the 1st film 2 and the 2nd film 3 with a press roller at the time of manufacture of the laminated | multilayer film 1, or making it roll shape. Even so, blocking of the laminated film roll 11 can be reliably prevented by the presence of the non-adhesive portion 7.
In the present invention, in order to adhere the one side edge 31 of the second film 3 to the first film 2, the adhesive layer 5 is provided with at least one side edge 51 up to the one side edge 31 of the second film 3. It only has to be done.

  However, as in the modification shown in FIG. 8B, the laminated film 1 provided so that the one side edge 51 of the adhesive layer 5 substantially coincides with the one side edge 31 of the second film 3 is manufactured. At times, a delicate adjustment of the bonding position of the second film 3 is required. In this respect, in the laminated film 1 in which the adhesive layer exposed portion 53 is formed, even when the second film 3 is bonded, the one side edge 31 of the second film 3 is bonded to the adhesive even if it is slightly displaced in the width direction. This is preferable because it can be reliably bonded through the layer 5.

Furthermore, in each said embodiment, although the non-bonding part 7 is provided in the substantially whole (except the other side part overlap margin) of the other surface side of a 2nd film, it shows to Fig.9 (a). As described above, the non-adhesive portion 7 may be provided in the vertical direction only in the region corresponding to the adhesive layer exposed portion 53. Further, as shown in FIG. 9B, in the laminated film 1 provided so that one side edge 51 of the adhesive layer 5 substantially coincides with one side edge 31 of the second film 3, The non-adhesion part 7 may be provided in the longitudinal direction only in the region corresponding to the one side edge 31 of the second film 3.
Thus, when providing the non-adhesion part 7 only in the area | region corresponding to the part which the adhesive agent goes outside from the one side edge 31 of the 2nd film 3, the width | variety of this non-adhesion part 7 is larger than the width | variety of this part. It is also necessary to form a little wider.

Further, in each of the above embodiments, the second film 3 is laminated on one side of the laminated film 1 except for the width corresponding to the one side overlapping margin for the center seal. As shown in FIG. 10 (a), the second film 3 is laminated on one side of the laminated film 1 except for a wider range (for example, about 20 to 80 mm) than the width equivalent to the one side overlap allowance. May be. On one side of the laminated film 1, the width of the range in which the second film 3 is not laminated includes at least a mechanical reading symbol 4 such as a bar code, and further details by fine characters (for example, 8 points or less). It is preferably formed to such an extent that an object display, description, etc. can be printed and displayed.
Thus, by giving the mechanical reading symbol 4 to the non-laminated range of the second film 3, for example, as shown in FIG. 10B, the second film 3 is formed into a cylindrical shape with the label surface side. In addition, the mechanical reading symbol 4 can be accurately displayed on the heat-shrinkable cylindrical label 10. That is, when the mechanical reading symbol 4 is printed on the design printing layer 6 of the first film 2 and the second film 3 is laminated so as to overlap the symbol 4, the mechanical reading symbol is used from the label surface using the reading device. It becomes difficult to read the reading symbol 4 accurately. In this regard, the second film 3 forms a non-laminated area, and the mechanical reading symbol 4 can be accurately read from the label surface by printing the mechanical reading symbol 4 in this range. In particular, the second film 3 is effective when a non-woven fabric, Japanese paper, or the like that is difficult to print barcodes or fine characters (for example, 8 points or less) is used.

  In each of the above embodiments, the other side edge of the laminated film 1 is aligned with the other side edge of each of the first film 2, the adhesive layer 5, and the second film 3. The other side edge of the two films 3 may be laminated while being displaced inward. In this case, similarly to the one side edge of the laminated film 1, at least the other side edge of the adhesive layer 5 is provided up to the other side edge of the second film 3, and the other end portion overlap is excluded, corresponding to it. It is preferable to provide a non-adhesive portion 7 in the region. Also in this case, the mechanical reading symbol 4 or the like can be printed on the portion where the second film 3 is not laminated.

Moreover, in each said embodiment, although at least any one of the 1st film 2 and the 2nd film 3 has heat shrinkability, a heat shrinkable laminated film is comprised by laminating this, 1st film A laminated film can also be constituted by using a film having no heat shrinkability for both the second film 2 and the second film 3 and laminating them. In addition, for example, as the first film 2, a film having self-stretchability (stretchability) can be used.
Furthermore, in each said embodiment, although the film which has heat shrinkability is used as the 1st film 2, a non-heat-shrinkable film is used as the 1st film 2, for example, and heat shrinkability is used as the 2nd film 3. It is also possible to use these films.

It is a center part partial omission perspective view which shows one Embodiment of a laminated | multilayer film, Comprising: The cross section in a width direction is shown collectively. (A) is a perspective view which shows one Embodiment of a cylindrical label, (b) is the top view which looked at the cylindrical label from the upper surface side. FIG. 3 is a sectional view taken along line AA in FIG. 2. 1 shows an embodiment of a method for producing a laminated film, (a) is a partially omitted plan view of a state in which a design printing layer and a non-adhesive portion are provided on the back surface of a first film original fabric, as viewed from the back surface side, (b). These are the reference front views seen from the arrow B direction of (a). In the manufacturing method, (a) is a partially omitted plan view of the state in which an adhesive layer is provided on the surface of the first film original fabric as viewed from the back side, and (b) is the direction of arrow C in (a). The reference front view seen from (c) is the reference front view which shows the state which adhere | attached the 2nd film original fabric on the adhesive bond layer. (A) is a partially omitted reference perspective view showing a laminated film roll, and (b) is a width direction showing an overlapping state of the first laminated film and the second laminated film in the laminated film roll. FIG. (A), (b) is sectional drawing in the width direction which abbreviate | omitted one part of the center part which shows the laminated | multilayer film concerning other embodiment. (A), (b) is sectional drawing in the width direction which abbreviate | omitted one part of the center part which shows the laminated | multilayer film concerning other embodiment. (A), (b) is sectional drawing in the width direction which abbreviate | omitted one part of the center part which shows the laminated | multilayer film concerning other embodiment. (A) is sectional drawing in the width direction which a part of center part which showed the laminated film which concerns on other embodiment was abbreviate | omitted, (b) is so that a 2nd film may become the label surface side in the laminated film. The top view which looked at the cylindrical label shape | molded in the cylinder shape from the upper surface side.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Laminated film, 2 ... 1st film, 2a ... One side of 1st film, 2b ... Other side of 1st film, 21 ... One side edge of 1st film, 22 ... Other side edge of 1st film, 23 ... 1st film exposed part, 3 ... 2nd film, 31 ... One side edge of 2nd film, 5 ... Adhesive layer, 51 ... One side edge of adhesive layer, 53 ... Adhesive layer exposed part, 6 ... Design printing Layers 7 ... Non-adhesive part (non-adhesive treatment) 10 ... Cylindrical label 11 ... Laminated film roll

Claims (5)

The second film is laminated and bonded to one surface of the first film via an adhesive layer,
The first film, the adhesive layer, and the second film each have one side edge and the other side edge extending in the longitudinal direction, and one side edge of the second film is located inside the one side edge of the first film. In the laminated film that is positioned and one side edge of the adhesive layer is provided to at least one side edge of the second film ,
Of the other surface of the first film, a region corresponding to a longitudinal belt-shaped region including at least one side edge of the adhesive layer is subjected to non-adhesion treatment for the adhesive of the adhesive layer. A laminated film. The adhesive layer is exposed between one side edge of the second film and one side edge of the first film by providing one side edge of the adhesive layer to the outside from one side edge of the second film. Part is formed,
The first of the other surface of the film, in a region corresponding to at least the adhesive layer exposed portion, the laminated film of the non-adhesion treatment decorated with it has claim 1.   The laminated film according to claim 2, wherein the adhesive layer exposed portion is formed thin.   The laminated film according to any one of claims 1 to 3, wherein the first film includes a synthetic resin film having heat shrinkability, and the second film includes a nonwoven fabric.   The cylindrical label formed by shape | molding the laminated | multilayer film in any one of Claims 1-4 in a cylinder shape by making the 2nd film into the label surface side.

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