JP2010160303A - Light-shielding print label for food container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a light-shielding print label for food containers, which has light-shielding properties without using a metallic material so that the light-shielding print label is not erroneously detected by the inspection using a metal detector at a quality control step. <P>SOLUTION: A white front surface layer for printing of the light-shielding print label for food containers is composed of a blended material of random polypropylene, a white master batch and an antistatic agent master batch. An intermediate layer for supporting the light-shielding printed label is composed of a blended material of: homo polypropylene; a filler master batch; and the white master batch. The back surface layer for shielding the light is composed of a blended material of: homo polypropylene; a color added and mixed black master batch (mixture of cyan colorant, magenta colorant and yellow colorant); and the antistatic agent master batch. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a light-shielding printed label for food containers.

Various in-mold labels for injection molding and blow molding have been developed.
The invention described in Patent Document 1 proposes a light-shielding resin container as a container for milk pudding, yogurt, cheesecake, raw milk, bavaria and the like.
These labels are placed in a container mold in a printed state and integrated with the injected resin to form a container. For this reason, the light-shielding printed label needs to prevent the entrance of light from the outside into the food container to prevent the food from being deteriorated, and to enable good printing on the surface.
On the other hand, many foods are inspected by a metal detector so that there is no contamination of the metal powder, but some of the existing light-shielding agents react to the magnetic field lines generated by the metal detector, causing false detection. May be.
Conventionally, in order to provide light-shielding properties, it is considered most advantageous to select a black agent as a colorant. In many cases, carbon black or iron oxide, which is a metal substance, is used as the pigment constituting the black agent. The light-shielding colorant used to impart this light-shielding property reacts with the magnetic field lines as described above, and may be mixed into food for some reason. Material selection is required.

Japanese Patent No. 3749914

(Carcinogenicity of carbon black)
Carbon black is considered to belong to group 2B (which may be carcinogenic) by the International Agency for Research on Cancer (IARC). Therefore, it shall not be used in the present invention.
The group classification is as follows.
・ Group 1: Carcinogenic ・ Group 2A: Probably carcinogenic ・ Group 2B: May be carcinogenic ・ Group 3: Cannot classify carcinogenic or do not know ・ Group 4: Probably not carcinogenic

  The object of the present invention is that the colorant used does not contain harmful substances such as carcinogenic substances, and has been described above, but in order to prevent false detection by metal detector inspection in the quality control process. An object of the present invention is to provide a light-shielding printed label for a food container having a light-shielding property without using a substance.

In order to achieve the above object, a light-shielding printed label for food containers according to claim 1 according to the present invention,
A white printing surface layer containing a random polypropylene, a white masterbatch, and an antistatic agent masterbatch,
An intermediate layer for support containing homopolypropylene, filler masterbatch, and white masterbatch,
And a light-shielding back layer containing a homopolypropylene, an additive-mixed black masterbatch, and an antistatic agent masterbatch.
The light-shielding printed label for food containers according to claim 2 according to the present invention is the light-shielding printed label for food containers according to claim 1,
The additive-mixed black masterbatch is a mixture of an indigo colorant (cyan pigment), a red colorant (magenta pigment), and a yellow colorant (yellow pigment).

The light-shielding printed label for food containers according to the present invention is summarized as follows, corresponding to the examples. That is, in the above-mentioned light-shielding printed label for food containers,
The thickness of the three-layer structure of the surface layer, intermediate layer, and back layer is 100 μm, and the layer composition ratio is 0.75: 5: 1.
The surface layer is a blend of random polypropylene (MFR = 7.5), white masterbatch (titanium oxide masterbatch), antistatic agent masterbatch (nonionic surfactant), and the blending ratio is 100: 10. : 0.5,
The intermediate layer is a mixture of homopolypropylene (MFR = 7.5), filler masterbatch (talc masterbatch), white masterbatch (titanium oxide masterbatch), and the blending ratio is 80:20:35. And
The backing layer is a blend of homopolypropylene (MFR = 7.5), black masterbatch (additive mixed black masterbatch), antistatic agent masterbatch (nonionic surfactant), Is 80: 20: 3.

  Since the light-shielding printed label for food containers according to the present invention is configured as described above, by in-molding the label in the container, the deterioration of contents due to external light is prevented, and the quality in each step Production accuracy can be improved without erroneous detection even in management.

It is an expanded sectional view of the light-shielding printed label for food containers by this invention. It is sectional drawing of the container which adhered the light-shielding printed label for food containers. It is a graph which shows the transmittance | permeability with respect to the wavelength of the Example of the light-shielding printed label for food containers by this invention. It is a graph which shows the transmittance | permeability with respect to the wavelength of the light-shielding printing label of the comparative example 1. It is a graph which shows the transmittance | permeability with respect to the wavelength of the light-shielding printing label of the comparative example 2.

Embodiments of a light-shielding printed label for food containers according to the present invention will be described below with reference to the drawings.
FIG. 1 is an enlarged cross-sectional view of an embodiment of a light-shielding printed label for food containers according to the present invention, and FIG. 2 is a cross-sectional view of a food container on which the embodiment label of FIG. The light-shielding printed label 1 for food containers is formed with a three-layer structure of a surface layer 1a, an intermediate layer 1b, and a back layer 1c. Printing is performed on the surface layer 1a, the surface layer 1a is directed outward, and is inserted into an inner wall of a mold for injection molding (not shown), and the resin of the container 2 is injected into the mold and integrally molded.
As shown in FIG. 2, a flange 3 is provided on the upper surface of the container 2. With the container filled with food, an aluminum foil (not shown) is adhered and sealed to the surface of the flange 3.

The film structure of the light-shielding print label according to the present invention is an unstretched three-layer (1a, 1b, 1c) structure. A light-shielding property is imparted to the back layer 1c using a colorant.
Conventionally, in order to give light-shielding properties, it is considered to be the best strategy to select a black agent as a colorant, and a comparative example that compares and contrasts with examples of light-shielding printed labels for food containers of the present application. As shown in No. 1 (described later with reference to Table 2), many of the pigments constituting the black agent use iron oxide, which is a metallic substance, and carbon black, which is a carcinogenic substance.

On the other hand, the present invention applies the principle of the three primary colors to provide light-shielding properties, and does not use any of the above-mentioned metallic substances, indigo colorant (cyan pigment), red colorant (magenta pigment) A mixture of yellow colorant (yellow pigment) is used as a black colorant (black color masterbatch).
Table 1 shows the details of the light-shielding printed label for food containers according to the present invention.

As shown in Table 1, the surface layer (1a) was blended with random polypropylene (MFR = 7.5), white masterbatch (titanium oxide MB (masterbatch)), and antistatic agent masterbatch (nonionic surfactant). The compounding ratio is 100: 10: 0.5.
The thickness of the three-layer structure of the surface layer (1a), the intermediate layer (1b), and the back layer (1c) is 100 μm as illustrated in FIG. 1, and the layer composition ratio is 0.75: 5: 1. It is.
MFR is a melt mass flow rate and is a numerical value indicating the characteristics of random polypropylene.

The intermediate layer (1b) is a mixture of homo PP (polypropylene) (MFR = 7.5), a filler master batch (talc MB), and a white master batch (titanium oxide MB), and the mixing ratio is 80: 20:35.
The back layer (1c) is a blend of homo PP (MFR = 7.5), black masterbatch (additive mixed black MB), antistatic agent masterbatch (nonionic surfactant) The ratio is 80: 20: 3.

Table 2 shows the details of the light-shielding printed label for food containers constituting Comparative Example 1 to be compared with the above-described Example label.

As shown in Table 2, the surface layer is a mixture of random polypropylene (MFR = 7.5), white masterbatch (titanium oxide MB), antistatic agent masterbatch (nonionic surfactant), Is 100: 10: 0.5.
The thickness of the three-layer structure of the surface layer, the intermediate layer, and the back layer is 100 μm, and the layer composition ratio is 0.75: 5: 1.

An intermediate | middle layer mix | blends homo PP (MFR = 7.5), a filler masterbatch (talc MB), and a white masterbatch (titanium oxide MB), Comprising: A compounding ratio is 80:20:35.
The back layer is a blend of homo PP (MFR = 7.5), black masterbatch (iron oxide MB), antistatic agent masterbatch (nonionic surfactant), and the blending ratio is 60:40. : 3.

Next, the light-shielding print label for food containers constituting Comparative Example 2 to be compared with the present embodiment label will be described. Comparative Example 2 is a product called a light-shielding printed label for food containers of other companies, and the details of the component layer composition ratio are unknown, but the thickness is 100 μm.
The color of the surface corresponding to the surface layer 1a of the present embodiment label is white, and the surface corresponding to the back layer 1c is black.

The target region for blocking external light of the label of the embodiment of the present invention is to block the transmittance to a negligible level at 500 nm and to block in the region of 400 nm or less (% T = 0), and maintain the blocking characteristics in the wavelength region beyond that to some extent. That is.
This is because it is known that light from a region of 400 nm or less may impair the quality of food such as dairy products. Most food companies also have standards that conform to this judgment.

The spectral characteristics of the present example label and Comparative Examples 1 and 2 were measured using the following spectrophotometer.
Device name: V-670
Model name: V-670
Serial number: A003661154

Accessory name: ILN-725
Accessories Serial No. : 456789
Regular reflection light: Including

Metering mode:% T
Measurement range: 2500-200 nm
Data capture interval: 1 nm
UV / Vis bandwidth: 5.0 nm
NIR bandwidth: 20.0 nm
Response: Fast
Scanning speed: 1000 nm / min
Light source switching: 340 nm
Diffraction grating switching: 850 nm
Light source: D2 / WI
Filter switching: Step correction: Baseline / Dark

The spectral transmittance measurement results of the above-described embodiment of the present invention, comparative example 1, and comparative example 2 are shown in FIGS. 3, 4, and 5, respectively.
In the present embodiment label (FIG. 3), the target value at which the transmittance (% T) indicating light shielding can be read is set to 400 nm. That is, effective light shielding (% T = 0) is obtained in a wavelength region of 400 nm or less.
In Comparative Example 1 (FIG. 4), a region that is not completely shielded appears from around 420 nm (% T = 0).
In Comparative Example 2 (FIG. 5), a region that is not completely shielded from light appears from around 400 nm (% T = 0).
In the embodiment of the present invention, a region that is not completely light-shielded appears from around 400 nm (% T = 0), and the region beyond it shows a lower light shielding degree than the former two.

The present Example label and the metal detector test result of Comparative Example 1 will be described. In Comparative Example 1, since the iron oxide master batch is used as the light shielding material, this hinders the detection accuracy of the metal detector. In this experiment, a light-shielding printed label for a food container itself was measured, and 10 specimens each of A4 size were prepared. In addition, the measurement about the comparative example 2 was not able to be performed. The details of the metal detector are shown below.
Metal detection measurement Measuring instrument: Nissin Electronics Co., Ltd.
Metal detector MS-3117-25S1
(Search coil model)
2. Phase angle setting: 55 °

The average output of the embodiment of the present application when measured while transporting the specimen on the conveyor of the metal detector is 0.2V, while that of Comparative Example 1 is 44.0V on average.
In Comparative Example 1, it is impossible to detect a magnetic substance such as a metal powder having a level of 44.0 V or less while the food to be inspected is conveyed on a conveyor for mass inspection (all product inspection). It will be. For example, it means that even if there is a reaction of about 0.2 V, it cannot be detected.
On the other hand, in the case of the embodiment of the present application, if there is a reaction of about 0.2V (due to a metal piece or powder), it is considered that there is a possibility that a suspicious object may be mixed, and a detailed inspection is performed in isolation. be able to.

About the above-mentioned Example of the present application, as a result of preparing an injection molded product as shown in FIG. 2 and measuring the label adhesion after molding, the following good measurement results were obtained.
Label adhesion measurement 1. Measuring instrument: Tensile strength tester
2. Unit: N / 15mm
3. Peel angle: 180 °
4). Peeling speed: 300 mm / min
This is comparable to conventional products.

DESCRIPTION OF SYMBOLS 1 Light-shielding printing label for food containers 1a Surface layer 1b Intermediate layer 1c Back layer 2 Container 3 Flange part of container

Claims (2)

A white printing surface layer containing a random polypropylene, a white masterbatch, and an antistatic agent masterbatch,
An intermediate layer for support containing homopolypropylene, filler masterbatch, and white masterbatch,
A light-shielding back layer formulated with homopolypropylene, additive color mixed black masterbatch, antistatic agent masterbatch,
A light-shielding printed label for food containers, comprising: In the light-shielding printed label for food containers according to claim 1,
The additive-mixed black masterbatch is a mixture of a blue colorant (cyan pigment), a red colorant (magenta pigment), and a yellow colorant (yellow pigment). Printed label.

Images