JPH0854826A - Label - Google Patents

Abstract

PURPOSE:To provide a label which is stuck simultaneously to a container in metal molds at the time of molding the container, etc., is composed of a propylene based copolymer, is subjected to vapor deposition of metal and is not whitened by loss of metallic gloss by this vapor deposition when adhering at the time of molding. CONSTITUTION:This label A is stuck to the container B via an adhesive layer 8 simultaneously in the metal molds at the time of molding the container B and consists of a label base material 3 composed of the propylene based copolymer and a printing layer 4 disposed on the rear surface side of this label base material 3. The printing layer 4 of such label A is subjected to the vapor deposition of the metal. The refractive index in a direction (Y) perpendicular to the vessel B of the label base material 3 described above is 1.513 to 1.520 and the refractive index in a direction (X) lateral to the container B is 1.493 to 1.500.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a label made of a propylene-based polymer which is simultaneously attached to a container such as a hollow container made of plastic such as polyethylene or polypropylene in a mold at the time of molding.

[0002]

2. Description of the Related Art In modern times, when molding a plastic hollow container or the like, a label attached to the container at the same time is often used in a mold, but shampoo, conditioner, cosmetics, etc. Since a beautiful label having a metallic luster is preferably used for the container, a metal such as aluminum is vapor-deposited also in the label.

[0003]

However, in the case of the conventional label having metal vapor deposition, there is a problem that the metal gloss is lost due to the vapor deposition and whitening occurs at the time of sticking at the time of molding, and a sufficient metal gloss is obtained. I couldn't do it.

The present invention has been made to solve the above problems, and is composed of a propylene-based polymer which is simultaneously adhered to a container in a mold during molding of the container and the like, and is made of metal. An object of the present invention is to provide a label which is vapor-deposited and which is not whitened due to loss of metallic luster due to the vapor deposition during sticking during molding.

[0005]

The present invention takes the following technical means in order to solve the above problems.

That is, when the container B is molded, the label A is attached to the container B via the adhesive layer 8 at the same time in the mold, and the label base material 3 is composed of a propylene-based polymer.
And a print layer 4 provided on the back side of the label base material 3, and the print layer 4 is provided with a metal vapor deposited label A.
In the above, the label base material 3 has a refractive index of 1.513 to 1.520 in the up-down direction (Y) with respect to the container B, and has a refractive index of 1 in the left-right direction (X) with respect to the container B. .493
It is characterized by being ˜1.500.

[0007]

The label A consisting of the label base material 3 and the printing layer 4 of the present invention is attached at the same time in the mold during the molding of the container B. Container B
On the other hand, the refractive index in the vertical direction (Y) is 1.513 to 1.520.
And the refractive index in the left-right direction (X) with respect to the container B is 1.493 to 1.500, even if the printed layer 4 is metal-deposited, Neither the vapor-deposited surface becomes cloudy and the metallic luster is lost, nor does the label A wrinkle, swell, bend, loosen, or the like.

Further, in the case of the label A having the average surface roughness (R _a ) of the side 2 adhered to the container B of 0.2 to 2.0 μm, the back surface 7 side of the label A is considerably Since the surface is roughened, air easily escapes from the gap 9 between the container B and the label A, and air bubbles are not held.
Therefore, the adhesiveness to the container B is very good, and the label A
It is possible to prevent the container B from swelling and to prevent the container B from being deformed, cracked, or cracked.

Further, in the case where the protective coating layer 5 is provided on the surface 2 side of the label A, the label is
Sufficiently prevent scratches and other fine scratches on A.

[0010]

EXAMPLE The label A of the present invention is composed of a propylene-based polymer, and as shown in FIG. 1, at the time of molding a hollow container B made of plastic or the like, the surface of the container B is simultaneously in the mold.
The outer surface of the container B is attached to the outer surface of the container B and the surface of the label 2
Is a so-called in-mold label that is provided substantially flush with the label A, and in particular, the label A is metal-deposited.

The label A has a refractive index in the vertical direction (hereinafter simply referred to as Y) of 1.513 to 1.
520, preferably 1.514 to 1.519, and having a refractive index of 1.493 to 1.500, preferably 1.494 to 1, in the left-right direction (hereinafter simply referred to as X) with respect to the container B. Label base material 3 which is .499 and the base material
3 and a print layer 4 provided on the back side of the label base 3, and the front side of the label base material 3, that is, the front side of the label A.
2 is provided with a protective coating layer 5 for preventing scratches, the printed layer 4 is provided with a vapor deposition layer 6 on which a metal such as aluminum is vapor deposited, and the surface of the vapor deposition layer 6 is further provided.
That is, the adhesive layer 8 is provided on the back surface 7 side of the label A for sticking to the container B.

The Y and X refractive indexes are obtained by calculating the ratio of the speed of light in air to the speed of light passing through the label base material 3 of the label A. The sine of the incident angle and the refractive angle It is expressed as the ratio of the sine of.

When the value of the refractive index is lower than the above range, after the label A is attached to the container B, the vapor-deposited layer 6 becomes cloudy and the beauty is lost, and conversely, the value of the refractive index is Is higher than the above range, when the label A is attached to the container B,
Wrinkles and distortions appear on the product itself, and the appearance after sticking to the container B deteriorates.

Examples of the propylene-based polymer used as the label substrate 3 include crystalline polypropylene, propylene / ethylene copolymer, propylene / butene-1 copolymer, or propylene / ethylene / butene-1.
Examples of the copolymer include a crystalline polymer containing propylene as a main component. Among these, the most preferable material for the label according to the present invention is propylene / ethylene / random copolymer, and particularly , Ethylene content 2
5% by weight.

Labels A according to the [0015] present invention, as shown in FIG. 2, the average surface roughness of the side 2 that is attached to the container B (hereinafter, simply referred to as R _a.) Is 0.2 to 2.0 [mu] m, It is preferably in the range of 0.5 to 1.5 μm, and its maximum surface roughness (hereinafter, simply referred to as R _max ) is 4 to 20 μm.
m, preferably in the range of 5 to 15 μm.

If R _a is smaller than the above range, air bubbles are likely to remain in the space 9 between the container B and the label A, often resulting in poor appearance. Also has poor adhesion. On the other hand, if the above R _a exceeds the above range, the probability that the container B will crack due to impact increases, and this tendency becomes remarkable as the container B becomes thinner.

Further, the R _max depends on the thinning of the container B, and when the R _max becomes larger than the above range,
In a thinned container, there is a high probability that the container B will crack or crack from the gap 9 between the container B and the label A.

However, it is better that R _a 'and R _max ' of the surface of the protective coating layer 5, that is, the surface 2 of the label A, is smaller, and specifically, the adhered side, that is,
It is preferably less than half of R _a and R _max of the surface 7 of the label A.

In the label A, this is the surface 2
This is because the side is the side to be viewed, and in order to enhance the appearance value of the label A and the container B, it is better to have gloss or gloss.

Next, with respect to the manufacturing method of the label A,
Specifically, an example of using a crystalline propylene / ethylene / random copolymer for the label substrate 3 will be given.
Detailed description.

First, a crystalline propylene / ethylene / random copolymer (ethylene content 4.0% by weight, melt flow index 3.0 g / 10 min) is added to a known antioxidant, organic slip agent, inorganic antiblocking agent. Prepare a pellet consisting of a small amount of
The pellets are fed to an extruder and melt extruded at a temperature of about 250 ° C.

Next, the molten pellets are extruded from the extruder and flow out from the T-type die to form a molten sheet.

Next, the surface temperature of the molten sheet is about 20.
Approximately 30 ℃
An unstretched sheet of 0 μm is formed.

Next, the unstretched sheet is heated to about 85 to 95 °.
After preheating to C, while heating with an infrared heater, it is stretched in the longitudinal direction at a stretch ratio of 3.0 to 4.0 times, and once stretched to 50
A uniaxially oriented sheet is wound around a chill roll of ° C and cooled to obtain a uniaxially oriented sheet, which is then heated again to 100 to 110 ° C and stretched 1.0 to 1.2 times in the width direction.

Next, the stretched sheet is heated to 110 to 140 °.
After heating to C, tension heat fixing for 15 seconds, and cooling to room temperature, one side of the sheet is subjected to corona discharge treatment, the wetting tension of the surface is increased to about 50 dynes / cm, and winding is performed. Form the film.

Next, after slitting the film to a predetermined width to form a product roll, the film is subjected to a gravure printing machine and the surface on the side subjected to the corona discharge treatment is, for example, from 2 to 6 colors. Is printed, characters, patterns,
A print layer 4 is provided by printing various designs, and aluminum is vacuum-deposited to a thickness of about 0.05 μm on the upper surface of the print layer 4 to provide a vapor deposition layer 6.

At this time, since the pattern on the printed layer 4 has a clear portion 10 (a portion without ink), the vapor deposition layer 6 is visually observed from the surface 2 side of the label A in the portion 10. be able to.

In order to improve the adhesion between the film surface and the vapor deposition layer 6, a transparent undercoat layer may be provided by printing or the like before the vapor deposition.

Next, an adhesive containing ethylene ethyl acrylate as a main component is applied to the upper surface of the vapor deposition layer 6 to form an adhesive layer 8.

The adhesive layer 8 has a particle size of 1 to 10 μm.
The silica particles of m 3 are added at various ratios to adjust the average surface roughness (R _a ) of the side adhered to the container B, that is, the back surface 7 of the label A, to 0.20 to 2.00 μm.

Next, a transparent ink or the like is applied to the surface of the film, that is, the upper surface of the label substrate 3 to form a protective coating layer 5. In addition, the protective coating layer 5
By incorporating an antistatic agent therein, it is possible to prevent dust, dirt, etc. on the label.

The print-processed film formed as described above is subjected to a label punching machine so that the direction of the uniaxial orientation of the film is adjusted to the vertical length when the film is attached to the container B, and the film is processed. A rectangular label A is obtained by appropriately punching the Y length of about 105 mm and the X length of about 60 mm.

The label base material 3 of the label A manufactured as described above has a refractive index in the Y direction of 1.513 to 1.
520, and the refractive index in the X direction is 1.493 to 1.
Will have 500.

A plurality of the above-mentioned labels A are housed in a makagin, taken out one by one with a suction cup, and transferred to a hollow container molding die. Incidentally, since the average surface roughness (R _a ) of the back surface 7 of the label A is adjusted to 0.20 to 2.00 μm, there is no problem such as taking two sheets at the time of taking out.

Next, the propylene / ethylene copolymer parison (resin temperature of about 210 ° C.) is blow-molded, and the adhesive layer 8 of the label A is placed on the surface 1 of the bottle container B in the mold.
To adhere to.

A label manufactured as described above, and
As shown in FIG. 3, using conventional labels having different refractive indexes, while sticking to the hollow container B, for a long time,
I evaluated its appearance. The results are shown in Table 1 below.

[0037]

[Table 1]

The visual evaluation is a three-level evaluation in which ◯ is good, Δ is slightly bad, and X is bad.

As a result of the above experiment, Examples 1 to 1 according to the present invention
It was found that the label in Example 3 can maintain a good condition without wrinkles, tightness, swelling, poor adhesion, inclusion of bubbles, and deformation of the container B.

The measuring method of the characteristic values such as the refractive index and the surface roughness of the label in the present invention, which is required in the above-mentioned manufacturing, is carried out by the following measuring method.

<Refractive index> Using an Abbe refractometer, JIS
Measure according to K 7105.

<Surface Roughness> The average surface roughness (R _a ) and the maximum surface roughness (R _max ) are measured according to JIS B 0601.

At this time, the cutoff was 0.80 mm, the measurement length was 4.5 mm, the surface of the label was randomly measured at 5 points, and R _a and R _max at each of the 5 points were simply arithmetically averaged. The surface roughness of the surface.

<Melt Flow Index> AST
It is measured under the condition L of MD 1238.

<Ethylene content> In the infrared spectrum,
Absorbance ratio between 720 cm ^-1 and 900 cm ^-1 (A720 /
A900).

[0046]

As described above, the label base material of the label according to the present invention has a refractive index of 1.5 relative to the container in the vertical direction (Y).
13 to 1.520 and in the left-right direction with respect to the container
Since the refractive index of (X) is configured to be 1.493 to 1.500, even if the printed layer is subjected to metal vapor deposition, the vapor deposition surface may become cloudy and lose the metallic luster. ,
In addition, wrinkles, swelling, bending, slack and the like do not occur on the label.

Further, in the above label, the average surface roughness (R _a ) on the side attached to the container is 0. In the case of 2 to 2.0 μm, since the back surface side of the label is considerably roughened, it is easy for air to escape from the gap between the container and the label, and it is possible to prevent inclusion of air bubbles. Therefore, the sticking property to the container becomes very good, the swelling of the label can be prevented, and the deformation, cracks, cracks and the like of the container can be suppressed.

Further, in the case where the protective coating layer is provided on the surface side of the label, it is possible to sufficiently prevent the label from being scratched or fine scratched.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a container to which a label of the present invention is attached.

FIG. 2 is an enlarged sectional view of the same.

FIG. 3 is a perspective view showing a container to which the label is attached.

[Explanation of symbols]

 1 surface of the container 2 surface of the label 3 label base material 4 printing layer 5 protective coating layer 6 vapor deposition layer 7 back surface of the label 8 adhesive layer 9 gap between the container and the label A label B container X left and right direction to the container Y container to the container Up and down

Front page continued (72) Inventor Hiroshi Harada 5-3-18 Imazukita, Tsurumi-ku, Osaka City Fuji Seal Industry Co., Ltd.

Claims (3)

[Claims] 1. A label (A) which is adhered to the container (B) at the same time in the mold via the adhesive layer (8) at the time of molding the container (B), and is composed of a propylene-based polymer. Label base material
(3) and a printing layer provided on the back side of the label substrate (3)
(4) and in the label (A) in which the printed layer (4) is vapor-deposited with metal, the label substrate (3) is bent in the vertical direction (Y) with respect to the container (B). The rate is 1.513-1.
A label having a refractive index of 520 and a refractive index of 1.493 to 1.500 in the left-right direction (X) with respect to the container (B). 2. In the label (A), the average surface roughness (R _a ) on the side attached to the container (B) is 0.20 to 2.00.
The label according to claim 1, wherein the label is μm. 3. The protective coating layer (5) is provided on the surface side of the label substrate (3).
Label as described.