JP2008007205A - Package - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a package that can be precisely sensed by infrared-ray irradiation regardless of the infrared reflectance of a printing ink layer. <P>SOLUTION: The package includes a container 4 with an opening portion, in which a content 7 is loaded, and the opening portion is closed with a lid material, wherein (1) the container is obtained by molding a transparent or translucent resin film, (2) the lid material has an infrared reflective layer with an infrared reflectance of 60% or more, (3) a printing layer 2 is formed on the container side from the infrared reflective layer, and (4) an infrared absorbing layer 3 with an infrared absorbance of 5% or more is formed on the container side from the infrared reflective layer, (5) a flat surface of the lid material is divided into a printing region that has the printing layer and a non-printing region that does not have the printing layer by forming the printing layer, and (6) the infrared absorbing layer is formed on (a) the printing region and non-printing region, or (b) the non-printing region. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a novel package.

  A press-through pack (PTP) package is used for packaging pharmaceuticals, health foods and the like having dosage forms such as tablets and capsules. In this package, an inspection (foreign matter inspection) for confirming whether foreign matter is not mixed is usually performed.

  However, conventional inspection methods and packages have limitations in the detection target range, detection accuracy, and the like. For example, the metal detector method cannot be applied to a package using an aluminum foil. In the photographic method or visual inspection, it is difficult to distinguish the printed layer from the package from foreign matter. It is difficult to detect organic substances by the X-ray inspection method.

  On the other hand, by processing a video signal obtained by photographing a PTP sheet with a CCD camera or the like by a specific method, even if there is a mesh pattern on the entire object to be inspected, it is easy to remove foreign matter without depending on illumination technology. A defect detection method that can detect the above has been proposed (Patent Document 1).

However, in the above method, when the PTP sheet has a printing portion, the printing portion cannot be distinguished from a foreign object. In this case, it is possible to specify the position of the printing part by pattern matching and mask the printing part in advance. There is a problem that it cannot be detected.
JP 11-39484 A

  The present inventor has already developed a package that is optimal for a foreign matter detection method using infrared irradiation in view of the above-described problems of the prior art. This is to increase the infrared reflectance of the printing ink layer to 50% or more by eliminating pigments having a low infrared reflectance. This makes it possible to make printing inconspicuous on the infrared image by bringing the infrared reflectance of the printed area close to the infrared reflectance of the area without the print layer. As a result, when inspecting the foreign matter present in the package, the inspection can be performed without masking the printed portion, so that highly accurate inspection is possible.

  However, in the above method, the purpose can be achieved by increasing the infrared reflectance of the printing itself. However, as a means for this, a pigment having a low infrared reflectance or transmittance is excluded, or a pigment having a high reflectance or transmittance. It is necessary to replace with. In this case, the color tone of the printing color originally required for printing may not be obtained. When it is necessary to use a pigment having a low infrared reflectance or transmittance in order to match the required color tone, the infrared reflectance is less than 50%, which may make it difficult to detect foreign matter with high accuracy.

  Accordingly, a main object of the present invention is to provide a package that can accurately detect by infrared irradiation regardless of the infrared reflectance of the printing ink layer.

  As a result of intensive studies in view of the problems of the prior art, the present inventor has found that a package having a specific printed layer can achieve the above object, and has completed the present invention.

That is, the present invention relates to the following package.
1. A package in which contents are loaded in a container having an opening, and the opening is closed by a lid,
(1) The container is obtained by molding a transparent or translucent resin film,
(2) The lid member has an infrared reflective layer having an infrared reflectance of 60% or more,
(3) having a printed layer on the container side from the infrared reflective layer,
(4) An infrared absorption layer having an infrared absorption rate of 5% or more is provided on the container side from the infrared reflection layer,
(5) By the formation of the printing layer, the lid is divided into a printing area having the printing layer and a non-printing area not having the printing layer in the plane of the lid.
(6) The infrared absorption layer is formed on a) a printing area and a non-printing area or b) a non-printing area.
A package characterized by that.
2. Item 2. The package according to Item 1, wherein the infrared absorption layer having an infrared absorption rate of 5% or more is a layer that absorbs 5% or more of near infrared rays having a wavelength of 800 to 900 nm.
3. Item 3. The package according to Item 1 or 2, wherein the infrared reflective layer is formed on the printing region and the non-printing region.
4). Item 4. The package according to any one of Items 1 to 3, wherein the infrared reflective layer is an aluminum foil layer.
5. Item 5. The package according to any one of Items 1 to 4, wherein a difference in infrared reflectance between the print region and the non-print region is 25% or less.
6). Item 6. The package according to any one of Items 1 to 5, wherein the visible light absorptance of the infrared absorbing layer is 20% or less.
7). Item 7. The package according to any one of Items 1 to 6, wherein the infrared reflectance of the printing region is less than 50%.
8). Item 8. The package according to any one of Items 1 to 7, wherein the infrared absorbing layer contains an infrared absorbing material.
9. Item 10. The package according to any one of Items 1 to 8, wherein the infrared absorbing layer contains at least one infrared absorbing material of carbon black, titanium oxide, zinc oxide, phthalocyanine green, and iron oxide.
10. The infrared reflective layer is a lid material made of an aluminum foil layer, and a printing layer and an infrared absorption layer are formed in this order from the aluminum foil layer to the container side, the infrared absorption layer has thermal adhesiveness, and the infrared absorption layer is The package according to Item 1, wherein the container is closed by a lid material, and a printed layer and a surface protective layer are formed in this order on the other surface of the aluminum foil layer.
11. A lid material in which the infrared reflective layer is an aluminum foil layer, and a printing layer, an infrared absorption layer and a thermal adhesive layer are formed in this order from the aluminum foil layer to the container side, and the container is closed by the lid material via the thermal adhesive layer. The package according to Item 1, wherein a printed layer and a surface protective layer are sequentially formed on the other surface of the aluminum foil layer.
12 Item 12. The package according to any one of Items 1 to 11, wherein the content is a drug.
13. Item 13. The package according to any one of Items 1 to 12, for use in a method of detecting the presence or absence of foreign matter in the package by irradiating infrared light from the container side of the package.
14 13. The package according to any one of Items 1 to 12, wherein (1) at least 1) the contents, 2) the container, and 3) an infrared ray on the surface of the lid on the side that closes the opening of the container A step of irradiating light including light, (2) a step of imaging a region irradiated with light including infrared light, and (3) presence / absence of foreign matter in the region from image image data obtained by imaging. The package for using for the foreign material detection method which has the process to determine.

The package of the present invention is a package in which contents are loaded in a container having an opening, and the opening is closed by a lid material,
(1) The container is obtained by molding a transparent or translucent resin film,
(2) The lid member has an infrared reflective layer having an infrared reflectance of 60% or more,
(3) having a printed layer on the container side from the infrared reflective layer,
(4) An infrared absorption layer having an infrared absorption rate of 5% or more is provided on the container side from the infrared reflection layer,
(5) By the formation of the printing layer, the lid is divided into a printing area having the printing layer and a non-printing area not having the printing layer in the plane of the lid.
(6) The infrared absorption layer is formed on a) a printing area and a non-printing area or b) a non-printing area.
It is characterized by that.
<Container>
The container used in the package of the present invention may be obtained by molding a transparent or translucent resin film, and if the material, shape, molding method, etc. are appropriately employed according to the type of contents, etc. good. For example, when a package that accommodates a plurality of contents separately is required, a resin film having a plurality of pocket portions can be used. As a material, for example, vinyl chloride, polypropylene and the like are preferable. The thickness of the resin film is not limited, but is preferably about 0.05 to 2 mm. This container can be formed by, for example, a method using a press (extrusion molding, deep drawing, etc.) or a method not using a press (vacuum forming, pressure forming, etc.). These moldings may be either cold molding or hot molding, or a combination of both.
<Cover material>
The lid member has an infrared reflecting layer having an infrared reflectance of 60% or more (particularly 70% or more). For example, in the present invention, it is preferable to use the base material of the lid material as the infrared reflecting layer. In this case, the infrared reflective layer is formed on a printing area and a non-printing area described later.

  The infrared reflective layer may be made of any material having the infrared reflectance described above, and a lid material including at least one of an aluminum-based material, a resin film, and paper can be suitably used. For example, an aluminum-based material may be used alone, or a paper layer, a resin film layer, or the like may be laminated on an aluminum-based material. Furthermore, it may be formed of a resin film alone or paper alone, or may be laminated by combining these with other materials.

  The aluminum-based material may be either aluminum or an aluminum-based alloy. Specifically, pure aluminum (JIS (AA) 1000 series, such as 1N30, 1N70, etc.), Al-Mn series (JIS (AA) 3000 series, such as 3003, 3004, etc.), Al-Mg series (JIS (AA)). 5000 series), Al-Fe series (JIS (AA) 8000 series, such as 8021, 8079, etc.). Regarding components such as Fe, Si, Cu, Ni, Cr, Ti, Zr, Zn, Mn, Mg, and Ga contained in the aluminum-based material, as long as they are within the known content range defined by JIS and the like. There is no problem.

  The aluminum-based material is desirably used in the form of a foil (sheet shape). In this case, the thickness is preferably 7 to 50 μm, particularly preferably 10 to 40 μm. By setting within this range, it is possible to obtain more excellent water resistance (moisture resistance), strength, handleability of the package, and the like. When an aluminum foil is used as the aluminum-based material, it may be any of a hard material, a semi-hard material, a soft material, etc., and may be appropriately selected according to the shape of the container, the type of contents, and the like. In addition, the aluminum foil can be molded, degreased / washed, anchor coated, overcoated, surface treated, and the like by a known method, if necessary. By using an aluminum foil, strength, barrier properties, storage stability, etc. as a packaging material can be effectively exhibited.

  When using paper, for example, pure white roll paper, kraft paper, fine paper, imitation paper, western paper, Japanese paper, various coated papers, and the like can be applied. These can be used alone or in combination of two or more. The thickness of the paper layer is preferably about 10 to 100 μm. By applying the paper layer, curling of the lid can be prevented, moderate rigidity can be imparted to the lid, and troubles during manufacturing of the package can be reduced. Moreover, there is also an advantage that dead hold property (shape retention of the container after opening) can be maintained at the time of opening.

  When the resin is used, for example, polyamide (nylon), polyethylene (particularly high-density polyethylene), polypropylene (particularly stretched polypropylene), vinyl chloride, ethylene-vinyl alcohol copolymer, polyethylene naphthalate, polyethylene terephthalate, or the like can be applied. These can be used alone or in combination of two or more. Among these, at least one of polyamide and polyester is preferable. These are desirably used as a resin film. In this case, the thickness of the resin film layer is preferably about 9 to 50 μm. By forming the resin film layer, the strength, puncture resistance, water resistance, tear resistance and the like can be further improved.

The lamination or adhesion method of each layer is not particularly limited, and a known method can be applied. For example, a dry lamination method using a two-component curable urethane adhesive such as polyester urethane or polyester, a co-extrusion method, an extrusion coating method, a thermal lamination method using an anchor coating agent, and the like can be given.
<Print layer>
In this invention package, it has a printing layer in the container side from the said infrared reflective layer. That is, a printing layer is formed between the infrared reflective layer and the container. By the formation of the printing layer, the lid material is divided into a printing area having the printing layer and a non-printing area not having the printing layer in the plane of the lid material. In other words, the printing layer is formed on a part of the surface of the lid member.

  In the present invention, the formation of the printing layer divides the lid material into a printing area having the printing layer and a non-printing area not having the printing layer in the plane of the lid material. For example, FIG. 7A shows a plan view of the lid member, and FIG. 7B shows a cross-sectional view of the X-X ′ cross section of the plan view. In FIG. 7, the print layer 1 is formed, and the area 2 when corresponding to the plan view is the print area. In the plan view, an area 3 other than the printing area 2 is a non-printing area.

  Thereby, for example, when infrared irradiation is performed in a state where no infrared absorption layer is present on the cover material, a difference in infrared reflectance occurs between the printing region and the non-printing region. In particular, when the infrared reflectance of the printing area is less than 50% (particularly 45% or less), the difference is generally large.

  If necessary, a printing layer can be provided also on the surface of the infrared reflection layer opposite to the side on which the printing layer is formed.

  These print layers are generally used for displaying letters, numbers, symbols, etc., but other displays may be used. When these displays are used as printing layers, their shape is generally the shape of the printing area.

  Further, the printing layer may be a single layer or a multilayer composed of two or more layers.

  What is necessary is just to form a printing layer using the coloring material of the at least 1 postscript of a pigment and dye. In the present invention, the infrared reflectance of the printing area is not particularly limited. That is, according to the present invention, it is possible to provide a package that can accurately detect foreign matter even when the infrared absorption rate is low.

  In particular, when the infrared reflectance (near-infrared reflectance) of the printing area is less than 50% (particularly 45% or less), the difference in infrared reflectance between the printing area and the non-printing area increases as described above. In addition, the effect of forming the infrared absorption layer becomes more remarkable. More specifically, the printing region preferably reflects near infrared rays having a wavelength of 800 to 900 nm to less than 50% (particularly 45% or less).

  The lower limit value of the infrared reflectance of the print area is not particularly limited, but is preferably about 20% or more, more preferably about 30% or more from the viewpoint of desired color tone and foreign matter detection accuracy. It is.

  The printing layer can be formed by a normal method as long as the above conditions are satisfied. For example, the printing layer can be formed using an ink containing a coloring material.

  As the coloring material, at least one of a pigment and a dye can be used. These pigments and dyes are known inorganic pigments (for example, barium sulfate, zinc white, iron black, yellow iron oxide, ultramarine, bitumen, talc, calcium carbonate, cobalt blue, red rose etc.), organic pigments (monoazo, condensed azo). , Anthraquinone, quinacridone, isoindolinone, thioindigo, pyrrolopyrrole, perylene, disazo, phthalocyanine, etc.), dyes, etc., depending on the type of contents and the material of the lid be able to.

  The content of the colorant is not particularly limited, but generally it is preferably about 1 to 30% by weight, particularly 3 to 15% by weight in the ink.

  The binder is not particularly limited, and examples thereof include nitrocellulose, polyvinyl butyral, phenol resin, maleic acid resin, alkyd resin, and acrylic resin. These can be used alone or in combination of two or more. The binder content is preferably about 5 to 30% by weight in the ink.

  The solvent is not limited, and for example, toluene, xylene, methyl ethyl ketone, isopropyl alcohol, thinner, ethyl acetate, methyl acetate, butyl cellosolve, butyl acetate, methanol, ethanol, butanol, hexane, acetone and the like can be used. These can be used alone or in combination of two or more. The amount of solvent used may constitute the remainder of the ink.

  In the above ink, rosin, diethylene glycol, amine, linseed oil, castor oil, stearic acid, oleic acid, etc., as required, dispersant, curing agent, anti-settling agent, softening agent, antioxidant, extender, Ultraviolet absorbers, leveling agents, surface conditioners, sagging inhibitors, thickeners, antifoaming agents, lubricants and the like may be added.

  As a method for forming a printing layer using the ink, a known printing method such as letterpress printing, intaglio printing, screen printing, offset printing, gravure printing, or the like can be applied. Moreover, after forming a printing layer, it can use for a drying process as needed. For example, it can be dried by setting the conditions at room temperature (20 ° C.) to about 250 ° C. for about 10 seconds to 10 hours. In the case of continuous drying, it may be designed so that it can be dried by blowing hot air or moved in an oven.

  Although there is no limitation on the color of the printed layer, it is desirable that the printed layer be black or brown from the standpoint of visibility. In particular, when the printing layer is black, it is preferable to use a mixed pigment composed of three types of pigments: a red pigment (for example, barium salt), a yellow pigment (for example, disazo yellow), and a blue pigment (for example, phthalocyanine blue).

The thickness of the print layer is not limited, but is preferably about 0.1 to 10 μm. Moreover, it is preferable that the weight (weight after drying) of a printing layer shall be about 0.1-10 g / m < ² >.
<Infrared absorbing layer>
The package of the present invention has an infrared absorption layer having an infrared absorption rate of 5% or more from the infrared reflection layer to the container side.

  The infrared absorption rate of the infrared absorption layer is 5% or more, preferably 8% or more. If the infrared absorption rate is less than 5%, the desired infrared absorption performance cannot be obtained, and as a result, the detection accuracy may decrease. In the present invention, the infrared absorptance is particularly an absorptance in the near infrared ray having a wavelength of 800 to 900 nm.

  The infrared absorption layer is formed on a) the printing area and the non-printing area or b) on the non-printing area. That is, it includes both a) a case where it is formed over the entire surface of the lid material, and b) a case where it is formed in the non-printing area and not in the printing area. In the case of a), the difference in infrared reflectance between the printing area and the non-printing area can be reduced by suppressing the infrared reflectance in both the printing area and the non-printing area. In the case of b), only the infrared reflectance of the non-printing area can be lowered, and in general, the difference in infrared reflectance can be made smaller than in the case of a).

  In the case of a), the infrared absorbing layer may be formed directly adjacent to the printing layer, or may be formed through another layer. Moreover, in the case of said a), as long as it shape | molds from the infrared reflective layer to the container side, any of the upper layer or lower layer of a printing layer may be sufficient. In the case of b), the infrared absorbing layer may be on the same plane as the printing layer or may be formed on a different plane.

  From the viewpoint of increasing the detection accuracy of foreign matter detection using infrared light, the difference in infrared reflectance between the printed region and the non-printed region is preferably as small as possible, particularly 25% or less, and more preferably 15% or less.

  The infrared absorbing layer may be formed using an ink containing an infrared absorbing material. The material is not limited as long as it can absorb infrared rays, but it is particularly preferable to use at least one infrared absorbing material of carbon black, titanium oxide, zinc oxide, phthalocyanine green, and iron oxide. Other materials (such as pigments) may be included as long as a predetermined infrared absorption rate is obtained.

  As the binder, the solvent and the like to be blended in the ink, the same ones used for the formation of the printing layer can be used. In particular, when the visible light absorption rate of the infrared absorption layer is 20% or less as described below, it is preferable to select a transparent material. Specifically, a colorless or colored transparent material or translucent material can be used.

  The amount of the infrared absorbing material used can be appropriately set depending on the desired infrared absorbing performance. However, it is desirable in terms of visibility that the infrared absorption layer has a visible light absorptivity of 20% or less (particularly 15% or less). From this point of view, the amount of the infrared absorbing material used is desirably 5% by weight or less, particularly 0.2 to 3% by weight in the infrared absorbing layer.

  The infrared absorbing layer may be formed in the same manner as when the printed layer is formed. Further, the infrared absorbing layer may be provided as an independent layer, or an infrared absorbing function is imparted by incorporating an infrared absorbing material in a layer other than the printed layer (for example, a thermal adhesive layer). It can also be combined.

  By forming the infrared absorption layer, even when the infrared reflectance of the printing region is low, the difference in infrared reflectance between the printing region and the non-printing region can be reduced. In the present invention, the infrared reflectance (F) when an infrared absorbing layer is provided can be determined by the following calculation.

F (%) = F ₀ × L
(F ₀ indicates the infrared reflectance of the printed region or the non-printed region when there is no infrared absorbing layer. L indicates the infrared attenuation rate by the infrared absorbing layer.)
Accordingly, the infrared reflectance of the printing area and the non-printing area when there is no infrared absorbing layer is 40% and 70%, respectively, while the infrared absorbing layer having an infrared attenuation rate of 30% is provided on the printing area and the non-printing area. The results shown in Table 1 are obtained.

  As described above, since the infrared attenuation factor is applied to both the print region and the non-print region, the respective infrared reflectances are 28% and 49%. As a result, the difference in infrared reflectance between the two regions is reduced. This means that the contrast between the print area and the non-print area is reduced. Thereby, when used for foreign matter detection by infrared light, foreign matter can be more accurately detected as the print area becomes less noticeable.

When the infrared reflectance of the print area is less than 50%, the above difference is generally large, so that the effect of the infrared absorption layer is relatively large. In particular, when the infrared reflectance of the printing area is less than 50% (and 45% or less) and the infrared reflectance of the non-printing area is 50% or more (more than 65%), infrared absorption The effect by the layer becomes more remarkable.
<Join container and lid>
As for this invention package, the container opening part is closed with the lid | cover material. This method is not particularly limited, and a known method can be applied. For example, a method using an adhesive may be mentioned. In the present invention, it is particularly preferable to use a heat sealing method in which a thermal adhesive layer (thermal adhesive resin layer) is interposed.

  A well-known thing can be used as said thermoadhesive resin. For example, high density polyethylene, medium density polyethylene, low density polyethylene, linear linear polyethylene, saturated polyester, linear saturated polyester, unstretched polypropylene, chlorinated polypropylene, ethylene-acrylic acid copolymer, ethylene-methacrylic acid copolymer Polymer, ethylene-ethyl acrylate copolymer, ethylene-methyl acrylate copolymer, ionomer, ethylene-ethyl acrylate-maleic anhydride terpolymer, polyolefin, carboxylic acid-modified polyethylene, carboxylic acid-modified polypropylene, carboxylic acid-modified ethylene -Vinyl acetate, vinyl chloride, polystyrene and the like. Commercial products such as a product name “Bondaine” manufactured by Sumitomo Chemical Co., Ltd. and a product name “Mersen M” manufactured by Tosoh Corporation can also be used. These thermal adhesive resins can be used alone or in combination of two or more.

  The thermal adhesive layer may be formed on at least one of the lid member and the container, but is particularly preferably formed on the lid member. The thermal adhesive layer can be formed by applying a liquid adhesive containing the resin or laminating a thermal adhesive film made of the resin. Although the thickness of the heat bonding layer is not limited, it is usually preferably about 2 to 100 μm.

  The heat sealing conditions can be changed as appropriate depending on the type of thermal adhesive to be used, the type of contents, and the like, but in general, it may be set at 140 to 260 ° C. for about 1 to 3 seconds.

After heat sealing, if necessary, a ring seal (also referred to as “line seal”) is applied so that the cross-sectional shape of the package is concave, or the cross-sectional shape is continuous. A mesh seal can be applied. Moreover, it can replace with the heat seal which uses a hot plate, and can also employ | adopt an ultrasonic seal, an induction heating seal | sticker, etc.
<Others>
As another layer, what is employ | adopted by the well-known PTP package can be used suitably as needed. For example, an anchor coat layer, a printed layer, a colored layer, a primer layer, an overcoat layer, and the like may be appropriately formed on the back surface of the infrared reflective layer (that is, the side opposite to the container side).
<Contents>
The contents loaded in the container of the present invention package are not particularly limited, and the contents filled and loaded in a known PTP package can be applied as they are. The content is preferably a solid. Examples thereof include drugs (medicines), foods, electronic parts, contact lenses, fragrances, and cleaning agents. In particular, it is suitable for drugs that require foreign matter inspection. The drug may be a tablet, a capsule, or the like.

  The contents may be printed (marked) as necessary. In this case, the printing is desirably a printing layer that does not absorb infrared rays. As such a printing layer, the same one as described above can be adopted.

The package of the present invention can be applied to foreign matter inspection using infrared light. More specifically, it can be suitably used for a foreign substance inspection method described later. By applying the package of the present invention to the above inspection method, it is possible to detect foreign matter with high accuracy.
<Embodiment>
Specific embodiments include the following configurations.

  The first embodiment is shown in FIG. This package is a lid material in which the infrared reflecting layer is the aluminum foil layer 1, and the printing layer 2 and the infrared absorbing layer 3 are formed in this order from the aluminum foil layer 1 to the container 4 side. The container 4 has adhesiveness, and the container 4 is closed with a lid material via the infrared absorbing layer 3, and the printed layer 5 and the surface protective layer 6 are formed in this order on the other surface of the aluminum foil layer 1. The container 7 is loaded with a content 7 (medicine). In this package, the infrared absorbing layer also serves as the thermal adhesive layer, and the package can be made thinner.

The second embodiment is shown in FIG. This package is a lid material in which the infrared reflection layer is the aluminum foil layer 1, and the printing layer 2, the infrared absorption layer 3, and the thermal bonding layer 4 are formed in this order from the aluminum foil layer 1 to the container 5 side, and thermal bonding is performed. A container 5 is closed with a lid material via a layer 4, and a printed layer 6 and a surface protective layer 7 are formed on the other surface of the aluminum foil layer 1 in this order. The container 5 is loaded with a content 8 (medicine). This packaging body is different from FIG. 1A in that an infrared absorption layer and a thermal adhesive layer are provided separately, and is suitable for obtaining a stronger infrared absorption effect.
<Use of the present package for foreign matter inspection>
The package of the present invention can be suitably used as a package used in a method for detecting the presence or absence of foreign matter in a package by irradiating infrared light from the container side of the package.

  Specifically, for example, the method can be applied to a method using a known inspection apparatus as disclosed in JP-A-2003-215047.

  That is, (1) at least 1) the contents, 2) the container, and 3) a step of irradiating the surface of the lid on the side of closing the opening of the container with light containing infrared light (first step), ( 2) A step of imaging an area irradiated with light including infrared light (second step), and (3) A step of determining the presence or absence of foreign matter in the region from the image image data obtained by the imaging (first step). It can be used for a foreign matter detection method having three steps). Hereinafter, this method will be described.

First Step In this step, at least 1) the contents, 2) the container, and 3) the surface of the lid on the side that closes the opening of the container is irradiated with light containing infrared light. As light including infrared light, light including infrared light and including light in a wavelength region other than infrared light (for example, visible light) can be applied.

  The irradiation time, irradiation region, intensity, and the like of light including infrared light can be adjusted as appropriate according to the type of contents. Moreover, a well-known thing can be used for the apparatus itself which irradiates the said light.

Second Step In this step, an image of a region irradiated with light including infrared light is captured. In the present invention, it is desirable to capture (two-dimensional imaging) reflected light from a region irradiated with light including infrared light by an imaging means having sensitivity to infrared light.

  Examples of the imaging means include a camera having sensitivity only to infrared light, and a camera having sensitivity to infrared light provided with a filter that transmits only infrared light. These may be known or commercially available. For example, a commercially available CCD camera or the like can be used.

Third Step In this step, the presence / absence of foreign matter in the area is determined from the image data obtained by imaging. The determination method is not particularly limited as long as it is a method capable of detecting a foreign substance in distinction from the printed layer. For example, the following method can be taken.

  In the image image data obtained from the imaging means having sensitivity to infrared light, the brightness of the contents is higher than the brightness of the container (resin film) regardless of the color of the contents. In addition, the brightness of the foreign matter on the contents, cracks, and chips of the contents is lower than the brightness of the contents, and the brightness of foreign matters on the resin film is lower than the brightness of the resin film. And when a printing layer is a layer which does not absorb infrared rays, the lightness difference of a printing layer and a resin film becomes very small. What is necessary is just to process the image which this brightness difference produced with a means as shown in FIG.

  FIG. 2 shows the configuration of the image processing means (23). This means includes an A / D converter (27), a shading correction means (28), a first binarization means (29), a first image memory (30), and a second binarization means (31). , Second image memory (32), determination memory (34), CPU and output interface (35), third image memory (33), visual inspection result and statistical data memory (36), camera timing control means ( 37) and the like.

  The A / D converter (27) converts the two-dimensional image data imaged by the CCD camera (22), which is an imaging means, from an analog signal to a digital signal. The converted image data is subjected to shading correction by the shading correction means (28) according to the data of the shading correction table (38), and then stored in the third image memory (33).

  Note that shading correction corrects variations in the brightness of infrared light caused by position differences when it is difficult to uniformly irradiate the entire imaging range of the resin film with light including infrared light. Can be done for.

  The corrected brightness data is binarized by the first binarization means (29) with the first threshold value δ1, and then stored in the first image memory (30) in sequence. Thereby, the 1st binarized image data of a resin film is formed. The first threshold value δ1 is for determining a foreign substance in an area where the contents exist (content area). As the first threshold δ1, for example, a value that is brighter than the resin film and foreign matter that are the background of the contents and darker than the contents is selected. In the present invention, the first threshold value δ1 is preferably set to a value slightly lower than the brightness of the contents.

  Further, the corrected lightness data is binarized by the second binarizing means (31) with the second threshold value δ2, and then stored in the second image memory (32). Thereby, the second binarized image data of the resin film is formed. The second threshold value δ2 is mainly for determining foreign matters present in the resin film. As the second threshold δ2, a value darker than the resin film and the print layer is selected. In the present invention, the second threshold δ2 is preferably set to a value slightly lower than the brightness of the resin film.

  The CPU and the input / output interface (35) execute programs such as various image processing programs while using the stored contents of the determination memory (34), and send control signals to the PTP packaging machine (11) or PTP This is for receiving various signals such as operation signals from the packaging machine (11). Thereby, for example, the defective sheet discharge mechanism of the PTP packaging machine (11) can be controlled. The CPU and the input / output interface (35) also have a function of sending display data to the monitor (24). With this function, binary or shaded image data, appearance inspection results, and the like can be displayed on the monitor (24).

  The appearance inspection result and statistical data memory (36) stores data such as coordinates relating to image data, appearance inspection result data, statistical data obtained by probabilistically processing the appearance inspection result data, and the like. These data can be displayed on the monitor (24) based on the control of the CPU and the input / output interface (35). Further, based on these data, the CPU and the input / output interface (35) can send a control signal to the PTP packaging machine (11). The keyboard (25) is used to input settings such as pass / fail judgment reference values stored in the judgment memory (34).

  The camera timing control means (37) controls the timing at which image data captured by the CCD camera (22) is taken into the A / D converter (27). This timing is controlled based on a signal from an encoder (not shown) provided in the PTP packaging machine (11), and an image is taken by the CCD camera (22) every time a predetermined amount of resin film is sent.

  Next, a specific example in the case where an appearance defect due to a foreign object is detected will be described with reference to FIGS.

  FIG. 3A is a part of the appearance inspection range of a resin film (PTP film) as a specific example (this inspection range is indicated as “P”). A container (pocket part) formed by molding a PTP film contains tablets as contents. It is assumed that the letter “C” is stamped on the tablet and the foreign matter Dx is attached. It is assumed that the character “123” is printed on the cover film serving as the cover material, and the foreign matter Dy is attached.

  The PTP film is picked up by a CCD camera, subjected to shading correction, and stored in the third image memory (33). For example, the brightness of the stored image on the line AA ′ in FIG. 3A is high in the content area (tablet area) as shown in FIG. 3B, and the cover film area and the foreign substance area are low. Become.

  Next, the routine R1 is executed according to the flowchart shown in FIG. In the routine R1, the “inspection determination accompanying the first binarization process” is executed by the image processing device (23) (mainly the CPU). First, in step S1, the image processing device (23) forms first binarized image data by the first binarization means (29), and stores this data in the first image memory (30). (First binarization process). That is, assuming that the first threshold value δ1 or more is 1 (bright) and the value less than the threshold value 1 is 0 (dark), the data on the line AA ′ in FIG. It is converted into binarized image data as shown in FIG.

  In step S2, chunk processing is executed on the first binarized image data stored in the first image memory (30). The block processing includes processing for specifying each connected component for 0 (dark) and 1 (light) in the binarized image data, and label processing for labeling each connected component. Here, the area occupied by each connected component specified is represented by the number of dots corresponding to the pixel of the CCD camera (22).

  In step S3, the image processing device (23) specifies a connected component corresponding to the tablet having the seal from the 1 (bright) connected components obtained from the first binarized image data. A connected component corresponding to a tablet is a connected component corresponding to a tablet easily (ie, a tablet connected component including a predetermined coordinate, a connected component having a predetermined shape, a connected component having a predetermined area, etc.). Area) can be specified. Therefore, in the present inspection range P, the tablet region J (see FIG. 3D) including the foreign matter Dx is specified.

  In step S4, the image processing device (23) calculates the area Sx of the foreign matter in the tablet region. That is, out of the 0 (dark) connected components obtained from the first binarized image data, those included in or connected to the coordinates of the tablet region specified in step S3 are extracted, and the area Sx is obtained. Accordingly, in the inspection range P, the area of the foreign matter Dx is calculated.

  In step S5, the foreign substance area Sx is compared with a predetermined criterion value Px. If the foreign substance area Sx is smaller than the determination reference value Px, the process proceeds to step S6, and non-foreign substance determination (normal determination) is performed. Accordingly, in the main inspection range P, it is determined whether or not the foreign matter Dx is a foreign matter by comparing the area of the foreign matter Dx with the determination reference value Px. In this way, in the routine R1, after specifying the tablet area, it is determined whether or not there is a foreign substance in the tablet area regardless of the presence or absence of the stamped portion.

  FIG. 5 is a flowchart showing the routine R2. In the routine R2, the “inspection determination associated with the second binarization process” is executed by the image processing apparatus (23). First, in step S11, the image processing device (23) creates second binarized image data by the second binarization means (31), and stores this data in the second image memory (32). Let That is, assuming that the second threshold value δ2 or more is 1 (bright) and the value less than the second threshold value δ2 is 0 (dark), the data on the line AA ′ in FIG. The target image is converted into binary image data as shown in FIG.

  In step S12, the same lump processing as in step S2 is performed on the second binarized image data stored in the second image memory (32).

  In step S13, the image processing apparatus (23) calculates the area Sy of the foreign matter Dy. That is, a 0 (dark) connected component obtained from the second binarized image data is extracted, and the area Sy is obtained. Therefore, in the inspection range P, the area Sy of the foreign matter Dy is calculated.

  In step S14, the foreign substance area Sy is compared with a predetermined criterion value Py. If the foreign substance area Sy is smaller than the determination reference value Py, the process proceeds to step S15 to perform non-foreign substance determination (normal determination). On the other hand, when the area Sy of the foreign material is equal to or larger than the determination reference value Py, the process proceeds to step 16 where foreign object determination (abnormality determination) is performed. Therefore, in the present inspection range P, the area of the foreign matter Dy is compared with the determination reference value Py, thereby determining whether or not the foreign matter Dy is a foreign matter. Thus, in routine R2, the presence or absence of foreign matter on the cover film is mainly determined regardless of the presence or absence of the print layer.

  The processing of the routines R1 and R2 is executed in the process of manufacturing (medicine packaging) of the PTP sheet, and the processing unit can be one PTP sheet. When at least one of the routines R1 and R2 is judged as foreign matter, the PTP sheet can be determined to be defective and discharged.

  The features of the present invention will be described in more detail below with reference to examples and comparative examples. However, the scope of the present invention is not limited to these examples.

Examples 1-6 and Comparative Examples 1-2
A packaging material composed of an OP coat layer / aluminum foil layer / printing layer / KL layer / thermal adhesive layer was used as a basic structure, and the function as an infrared absorbing layer was imparted to the KL layer or thermal adhesive layer. Table 2 shows the pigment type and mixing ratio in the infrared absorbing layer, and the pigment type and content used in the printed layer.

The configuration of each layer was as follows.
(1) OP coat layer:
A coating agent mainly composed of nitrocellulose was applied and formed by a gravure method so that the weight after drying was 1.6 g / m ² .
(2) Aluminum foil layer:
A hard aluminum foil layer of JIS 1N30 and a thickness of 20 μm was used.
(3) Print layer:
It was formed using a printing ink adjusted to have a pigment ratio shown in Table 2 (ratio (% by weight) in solid content). Nitrocellulose (8% by weight in printing ink) and polyvinyl butyral (8% by weight in printing ink) were included as binders. The printed layer was divided into a printed region and a non-printed region in advance, and the printed layer was formed in the printed region by gravure printing so that the weight after drying was 1.2 g / m ² .
(4) KL layer (key lacquer layer):
A coating agent composed of a vinyl chloride-vinyl acetate copolymer was applied to the entire surface including the printing area and the non-printing area. The coating amount was set so that the weight after drying was 1.5 g / m ² . About Examples 1-5, as shown in Table 2, the pigment was contained (weight% in solid content), and the function as an infrared rays absorption layer was given.
(5) Thermal adhesive layer:
A thermal adhesive layer was formed on the outer surface of the KL layer using a coating agent comprising a vinyl chloride-vinyl acetate copolymer so as to have a weight of 4.0 g / m ² after drying by gravure printing.

Test example 1
About the sample obtained in each Example and Comparative Example, 1) Transparency of the infrared absorption layer, 2) Infrared absorption rate of the infrared absorption layer, 3) Visible light absorption rate of the infrared absorption layer, 4) Print area and non-printing The difference in infrared reflectance in the region was measured respectively. The results are shown in Table 2. Each measurement method was performed as follows.

1) Transparency of the infrared absorbing layer Judging by visual observation, the color tone of the printed region and the non-printing region (the portion where only the aluminum foil layer can be seen through) is different from the color tone when no pigment (in the infrared absorbing layer) is present. When not significant, it was evaluated as “good”, and when the difference was significant, it was evaluated as “bad”.

2) Infrared absorptivity of infrared absorbing layer The infrared absorptive layer was determined as the difference between the infrared reflectance of the aluminum foil alone as the infrared reflecting layer and the infrared reflectance of the non-printing area. The infrared reflectance was an average value of the reflectance when irradiated with infrared rays having wavelengths of 800 nm, 825 nm, 850 nm, 875 nm, and 900 nm, respectively.

3) Visible light absorptivity of infrared absorbing layer It was determined as the difference between the visible light reflectance of the aluminum foil alone and the visible light reflectance of the non-printing area. Moreover, the visible light reflectance was made into the average value of the reflectance when irradiating each visible light with a wavelength of 350 nm, 450 nm, 550 nm, 650 nm, and 750 nm.

4) Difference in infrared reflectance between the printing area and the non-printing area The difference was obtained by subtracting the infrared reflectance of the printing area from the infrared reflectance in the non-printing area.

  In addition, as said measuring apparatus, the ultraviolet visible near-infrared spectrophotometer (Product name "JASCO V570 type | mold" JASCO Corporation make) was used. An outline of the measurement method using the photometer is shown in FIG. The specifications of the photometer were as follows: holder type: integrating sphere type, measurement size: length 8 mm × width 9 mm, integrating sphere inner diameter: 60 mm, integrating sphere inner wall coating agent: barium sulfate.

It is a figure (sectional view) which shows an example of this invention package. It is a figure which shows the structure of the image processing means (23) used with this invention inspection method. It is a figure for demonstrating the specific example in which a foreign material is detected in a foreign material inspection method. It is a flowchart which shows the routine of "the test | inspection determination accompanying a 1st binarization process" performed by the image processing apparatus. It is a flowchart which shows the routine of the "inspection determination accompanying a 2nd binarization process" performed by the image processing apparatus. It is the schematic which shows the photometer used in the Example, and its measuring mechanism. It is a figure which shows the relationship between the printing area | region and non-printing area | region in this invention package.

Claims (11)

The container having an opening is filled with the contents, the opening is closed by a lid, and the package body is irradiated with light containing infrared light to detect the presence or absence of foreign matter in the package. A package used for a method of detecting,
(1) The container is obtained by molding a transparent or translucent resin film,
(2) The lid member has an infrared reflective layer having an infrared reflectance of 60% or more,
(3) having a printed layer on the container side from the infrared reflective layer,
(4) An infrared absorption layer having an infrared absorption rate of 5% or more is provided on the container side from the infrared reflection layer,
(5) By the formation of the printing layer, the lid is divided into a printing area having the printing layer and a non-printing area not having the printing layer in the plane of the lid.
(6) The infrared absorption layer is formed on a) a printing area and a non-printing area or b) a non-printing area.
A package characterized by that. The package according to claim 1, wherein the infrared absorption layer having an infrared absorption rate of 5% or more is a layer that absorbs 5% or more of near infrared rays having a wavelength of 800 to 900 nm. The package according to claim 1 or 2, wherein the infrared reflecting layer is formed on the printing area and the non-printing area. The package according to any one of claims 1 to 3, wherein the infrared reflective layer is an aluminum foil layer. The package according to any one of claims 1 to 4, wherein a difference in infrared reflectance between the printing area and the non-printing area is 25% or less. The package according to any one of claims 1 to 5, wherein the infrared ray absorbing layer has a visible light absorptance of 20% or less. The package according to any one of claims 1 to 6, wherein the infrared reflectance of the printing region is less than 50%. The package according to any one of claims 1 to 7, wherein the infrared absorbing layer contains an infrared absorbing material. The package according to any one of claims 1 to 8, wherein the infrared absorbing layer contains at least one infrared absorbing material of carbon black, titanium oxide, zinc oxide, phthalocyanine green, and iron oxide. The package according to any one of claims 1 to 9, wherein the content is a drug. The package according to any one of claims 1 to 10, wherein (1) at least 1) the contents, 2) the container, and 3) an infrared ray on the surface of the lid on the side of closing the opening of the container A step of irradiating light including light, (2) a step of imaging a region irradiated with light including infrared light, and (3) presence or absence of foreign matter in the region from image image data obtained by imaging. The package for using for the foreign material detection method which has the process to determine.

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