JPH0529471Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] The present invention relates to a package for a strip-shaped photographic material such as photographic paper or photographic film wound into a roll.

[Conventional technology]

Japanese Utility Model Publication No. 55-113543 discloses, as shown in FIGS. 14 and 15, a package of the above-mentioned strip-shaped photographic light-sensitive material, in which the strip-shaped photographic light-sensitive material wound into a roll is protected from light and moisture. The following has been proposed as a package for photosensitive strips that is protected and easily loaded into equipment in room light. That is, it includes a roll 31 of photosensitive strip wound into a roll of increasing radius and having a generally flat end face, and a cover 32 for each end face of said roll 31, each end cover 32 covering a peripheral face of said roll. In the packaging of photosensitive materials, the rim 33 has a rim 33 extending in the shape of a roll and fixed thereto, the rim 33 having a slit 34 extending generally in the axial direction of the roll. This packaging is characterized in that it ends so as not to reach the end face.

The band-shaped photographic light-sensitive material packaged in this way is loaded into a light-shielding container 35, and the light-shielding container 35 is
is pulled out from the slit opening 36 of.

[Problem that the invention attempts to solve]

Although the above-mentioned invention has a sufficient function in terms of protecting the strip-shaped photographic light-sensitive material wound into a roll from light and moisture, it has some disadvantages in terms of suitability for use. That is, when the package of the strip-shaped photographic light-sensitive material according to the above invention was loaded into a light-shielding container and pulled out through the slit opening of the light-shielding container and passed through, the rim was torn from the cover and stuck to both sides of the light-shielding leader. Since the strip of photosensitive material is pulled out in this state, the unevenness of the rim rubs against or connects with the slit opening, causing trouble in pulling out the strip of photosensitive material.

In addition, as a band-shaped photographic light-sensitive material package,
There were light-shielding containers described in Publication No. 55-124140, Japanese Utility Model Application Publication No. 55-88980, and Japanese Patent Publication No. 59-36736. However, although these light-shielding containers have the function of protecting the rolled photographic light-sensitive material strip from light, they do not have the same function as protecting the container against external shocks and from dust, moisture, and gas. There was a problem.

These light-blocking containers also have an unappealing appearance, are extremely prone to light-blocking-related problems if exposed to sunlight during the shipping process, and are made with light-absorbing colors that can cause the light-blocking containers to heat up. The photographic performance of the strip-shaped photographic material inside was often deteriorated.

The present invention solves the drawbacks of the prior art, and allows the strip-shaped photographic material to be smoothly pulled out from the outlet of the light-shielding container, and to remove light, moisture, and harmful gases from the strip-shaped photographic material, which is wound into a roll. An object of the present invention is to provide an improved package for a band-shaped photographic material that protects the material from damage.

[Means for solving problems]

In order to achieve the above-mentioned object, the present invention provides a light-shielding container with light-shielding thermometer cloth provided above and below the drawer opening, which is hermetically packaged in a sealed bag.

That is, the strip-shaped photographic material package includes a core that rotatably supports the strip-shaped photographic light-sensitive material wound into a roll, and loop-shaped piles provided above and below the longitudinal side of the outlet from which the strip-shaped photographic light-sensitive material is pulled out. A light-shielding container with a light-shielding thermoplastic cloth and an aluminum vacuum-deposited thermoplastic resin film layer with a thickness of
A sealed bag in which the light-shielding container is hermetically packaged with a laminated film having a heat-sealing layer laminated directly or via an adhesive layer on a 55-1200 Å vacuum-deposited aluminum film layer and having a moisture permeability of 10 g/m ² 24 hours or less. It is characterized by having the following.

The light-shielding container is used to store a strip of photographic light-sensitive material in a dark room and to mount it on a printer in a bright room. This light-shielding container is formed into a predetermined shape from paper, plastic, etc., and is provided with a core that rotatably supports the strip-shaped photosensitive material inside.
A slit-shaped outlet is formed for unwinding the strip-shaped photographic material from the core and leading it out of the light-shielding container.

Above and below the outlet in the longitudinal direction, light-shielding terremp cloth having loop-shaped piles is provided. The light-shielding terempu cloth having the loop-shaped pile is used to ensure the light-shielding properties of the outlet. It is preferable that the light-shielding terempu cloth having a loop-shaped pile not only has light-shielding properties but also be flexible so as not to damage the strip-shaped photographic light-sensitive material when the strip-shaped photographic light-sensitive material is pulled out or rewound.

The light-shielding terempu cloth with a loop-shaped pile of the present invention can be produced at a low cost through a relatively simple process, and there is no problem such as shedding or fraying (Ina).
This is a light-shielding member that covers the surface of a woven or knitted fabric with piles. As the light-shielding terremp cloth having looped piles, terremp cloth colored with dyes, pigments, etc. is preferable. In particular, black is preferable in terms of ensuring light-shielding properties.

An example of a terempu structure having loop-shaped piles is a pile weave in which loops are woven on one or both sides of the fabric. Usually, it is made with warp or weft double weave, but when the loops are created using warp threads, it is called warp pile weave, and when the loops are created using weft threads, it is called weft pile weave. The warp (or weft) yarns that create the loops are called the warp (or weft), and the warp and weft yarns that create the ground texture are called the ground warp and ground weft, respectively.

A method of creating loop-like piles on the surface of a terem cloth without using a pile weave is to deeply raise the diagonal or satin weave using a raising machine.

Methods for making terempu cloth with loop-shaped piles from textiles include terempu cloth in which so-called horizontal knitted knitted stockinettes, such as circular knitting and flat knitting, are raised into loop-shaped piles,
There is a method of making terempu cloth by brushing so-called warp knitted stockinette, such as tricot knit, ratssel knit, Milanese knit, etc., into a loop-shaped pile.

Further, as a method for directly producing a knitted fabric having a loop-shaped pile without a raising process, there are a method using a circular knitting pile knitting machine and a method using a circular hosiery pile knitting machine. A type of circular pile is the sinker pile.

Particularly preferred are sinker-pile yarn terempu fabrics made of black-colored polyester fibers, acrylic fibers, and synthetic fibers containing 50% or more of nylon and knitted with loop-shaped piles using a circular knitting machine, and terempu fabrics made using a tricot-to-vertical knitting machine. This is French pile yarn terempu cloth, which is made by manufacturing knitted fabric using a needle, then pulling out the horizontal threads with a needle and pulling them out into a loop to create a pile.

The warp and pile yarns used in the light-shielding cloth are synthetic fibers made of thermoplastic resin (nylon,
Acrylic yarn fiber, polyester fiber, vinylon,
(vinyl chloride fibers, vinyl chloride, vinylidene copolymer fibers, polypropylene fibers, polyethylene fibers, polycarbonate fibers, etc.) can be melt-cut using methods such as heat slitting or ultrasonic slitting to prevent the cut surfaces from fraying. It is preferable because it is superior to natural fibers in various respects, including uniform production and quality, low hygroscopicity, good heat setting properties after raising, and high physical strength.

However, depending on the required characteristics, synthetic fibers, rayon,
Single fibers such as acetate, cotton, and silk fibers, specially processed fibers, or fibers spun in a mixture of two or more types can be selectively used.

In addition, the light-shielding terempu cloth with loop-shaped piles also has continuous pile threads, so it is moisture-proof, which is another essential packaging material of this invention.
Even if a package sealed with a laminated film that has a light-shielding function is left in the printer for a long time under high temperature and high humidity after opening the sealed package, the photosensitive film that uses gelatin will swell and become sticky. Despite the increase in size, there is no pile layer attached to the photoresist film.

In the present invention, a light-shielding terempu cloth having loop-shaped piles means that all the piles may be loop-shaped or some of the piles may be loop-shaped, but it always has loop-shaped piles.

The light-shielding container is sealed and packaged in a sealed bag. This sealed bag not only ensures the dust-proofing, waterproofing, moisture-proofing, gas barrier, and heat-proofing properties that light-shielding containers lack, but also further improves light-shielding properties, product protection, stain prevention, and improved product value. This is to ensure that This sealed bag is provided in close contact with the entire surface of the light-shielding container, and the end portions are hermetically sealed by heat sealing or the like, so that the light-shielding container is completely hermetically packaged.
Further, the sealed bag may be a double bag to further ensure the above-mentioned dustproof property.

This sealed bag is made of a laminated film consisting of an aluminum vacuum-deposited thermoplastic resin film layer and a heat-sealing layer.

The aluminum vacuum-deposited thermoplastic resin film layer is a thermoplastic resin film formed with an aluminum vacuum-deposited film having a thickness of 55 to 1200 Å. Although any thermoplastic resin film can be used, various polypropylene films, various nylon films, various polyethylene films, and polyester films are preferable because they have high physical strength, are easy to obtain, and are relatively inexpensive. .

Further, the thickness of the thermoplastic resin film is preferably 7 to 50 μm from the viewpoint of vapor deposition cost, film cost, balance between ensuring openability and ensuring physical strength.

Most preferred are uniaxially or biaxially oriented (including stretched) polypropylene films, polyester films, polyethylene films, and nylon films with a thickness of 8 to 30 μm. Among polypropylene films, unstretched films are also preferred because they have high physical strength and are inexpensive. An ultra-thin reinforced film made of high-density polyethylene resin with a high blow ratio is particularly preferred because it has high physical strength and is inexpensive.

The thickness of the aluminum vacuum-deposited film is 55 to 1200 Å from the viewpoint of ensuring moisture-proofing, waterproofing, gas barrier, light-shielding, heat-proofing, antistatic properties, strength of the deposited film, etc., and quality such as cost and aesthetics. That is, if the thickness is less than 55 Å, the vacuum-deposited aluminum thermoplastic resin film alone cannot reduce the electrification generated on both sides of the vacuum-deposited aluminum film, and the thickness of the thermoplastic resin film or flexible sheet layer must be increased. Otherwise, it will not be possible to ensure the moisture-proofing, gas-barrier, and light-shielding properties necessary to protect the quality of photographic materials.

If the thickness exceeds 1200 Å, antistatic, moisture-proof, and light-shielding properties can be ensured, but due to cost and vacuum evaporation methods, the thermoplastic resin film may deteriorate due to heating.
There are problems such as a decrease in the physical strength of the resulting laminated film, making it difficult to put it into practical use. The thickness of aluminum vacuum evaporated film is more than 55 Å, 80 ~ for normal applications
A thickness of 800 Å is preferred, more preferably 100-
It is 600Å.

In order to improve the adhesion (also called adhesion) between the thermoplastic resin film and the aluminum vacuum-deposited film, the surface of the thermoplastic resin film is activated by various known methods, or an undercoat layer (anchor agent coat layer) is applied.
You may also make a profit.

A typical method for improving the adhesion strength between a vacuum-deposited aluminum film and a thermoplastic resin film will be described, but the present invention is not limited to these methods, and all known methods can be used.

(1) A method for activating the surface of the thermoplastic resin film layer 15.

(1) A method of activating the surface by corona discharge treatment.

(2) A method of activating the surface by UV irradiation treatment.

(3) A method of activating the surface by flame treatment.

(4) A method of activating the surface by dichromic acid treatment.

(5) A method of activating the surface by treating with an oxidizing agent such as a sulfuric acid mixture.

(2) A method of applying a substance with good affinity for metals and excellent metal receptivity to the surface activated in (1) (anchor agent application method) (1) A method of applying a polyester resin solution.

(2) Method of applying polyamide resin solution.

(3) Method of applying polyurethane resin solution.

(4) Method of applying epoxy resin solution.

(5) Method of applying cellulose derivative resin solution.

(6) Method of applying polyvinyl acetate resin solution.

(7) Method of applying polyvinyl butyral resin solution.

(8) Method of applying EAA, EEA, EMA resin solution.

(9) Methods of applying anchor coating agents such as titanium-based, imine-based, isocyanate-based, etc.

(3) Before aluminum vacuum deposition, the thermoplastic resin film layer is undercoated with epoxy resin or other resin (2).
A method in which a protective layer such as butyral resin is overcoated after aluminum vacuum deposition.

(4) A method of short-term heat treatment at a temperature around the melting point of the thermoplastic resin film layer before or after aluminum vacuum deposition.

(5) A substance having good affinity with metals is added to the thermoplastic resin film layer forming the aluminum vacuum-deposited film.

As the heat-sealing layer, any known heat-sealable layer may be used, such as a hot melt laminate layer, an extrusion laminate layer (including a coextrusion laminate layer), a wet laminate layer, a dry laminate layer, or a layer laminated with a separately formed film. In particular, a heat-seal layer formed by laminating a separately molded film using a thermoplastic resin, an extrusion laminate layer, a hot melt laminate layer, and a dry laminate layer are preferable because they are inexpensive and cause less curl.

Representative examples include various polyethylene resins, ionomer resins, ethylene-propylene copolymer resins, ethylene-vinyl acetate copolymer resins (EVA), ethylene-ethyl acrylate copolymer resins (EEA), and ethylene-methyl acrylate. Copolymer resin (EMA), ethylene-acrylic acid copolymer resin (EAA), and these thermoplastic resins
A blend of two or more types is preferred, and a heat-sealing layer containing as main components an EEA resin and a high-pressure low-density polyethylene resin or a linear low-density polyethylene resin is particularly preferred because it is inexpensive and has good heat-sealability. Even if the heat-sealing layer is a single layer, it can be two or more layers (including co-extruded heat-sealing layers).
It may be.

The aluminum vacuum-deposited thermoplastic resin film layer and the heat seal layer are laminated directly or via an adhesive layer. In order to directly laminate these materials, all methods such as extrusion lamination method and various coating methods can be used. In addition, in the case where a separately formed film is laminated via an adhesive layer, all known adhesives such as a polyolefin thermoplastic resin hot-melt adhesive can be used as the adhesive layer.

In addition to protecting the aluminum vacuum-deposited film layer,
If necessary, a protective layer may be provided on the aluminum vacuum-deposited film layer in order to improve the strength between the aluminum vacuum-deposited film and the heat seal layer or the adhesive layer, or to adjust the interlayer strength.

As the aluminum vacuum vapor deposited film protective layer, butyral resin, acrylic resin, cellulose resin such as cellulose acetate, urethane resin, epoxy resin, polyester resin, ionomer resin, EEA resin,
Appropriate resins such as various polyethylene resins and polypropylene resins can be used. Also wax, gelatin,
Polyvinyl alcohol and the like can also be used. The protective layer of vacuum-deposited aluminum film is preferably formed to have an extremely thin thickness. Even when using the extrusion lamination method, static electricity will not be removed sufficiently unless the thickness is 50 μm or less.

It is preferable to use a known solution coating method, spray coating method, or the like to achieve a thickness of 5 μm or less, since this not only protects the aluminum vacuum-deposited film layer but also increases the effect of preventing static electricity.

The laminated film of the present invention, which includes at least an aluminum vacuum-deposited thermoplastic resin film layer and a heat-sealing layer, has a moisture permeability of 10 g/ ^m2 for 24 hours or less, and also has improved physical strength, moisture resistance, and heat resistance. , another flexible sheet layer can be laminated on the opposite side of the heat-sealed side for the purpose of preventing curling or the like.

In this case, it is preferable to use a transparent or translucent flexible sheet layer to ensure the silver color of the aluminum vacuum-deposited film layer.

Preferred transparent or translucent flexible sheet layers are cellophane and monoaxially or biaxially oriented (including stretched) thermoplastic resin films. In this case, it may be a single layer film or a coextruded film having two or more layers. Among molecularly oriented (including stretched) thermoplastic resin films, biaxially stretched polyester films, various polypropylene films, various nylon films, and various polyethylene films are preferred in terms of availability, cost, physical strength, heat resistance, transparency, etc. Particularly preferred. Especially from the heat seal layer
A flexible sheet layer having heat resistance of 10° C. or higher is preferred.

[Effect]

The above-mentioned package for a strip-shaped photographic light-sensitive material has a light-shielding container with a light-shielding thermometer cloth having loop-shaped piles above and below the outlet for the strip-shaped photographic light-sensitive material. In particular, it is possible to prevent the photographic material from being exposed to light even when it is supplied.

A laminated film with a moisture permeability of 10 g/m ² 24 hours or less, which has a heat-seal layer directly or via an adhesive layer on the aluminum vacuum-deposited thermoplastic resin film layer with a thickness of 55 to 1200 Å. By tightly packaging the light-shielding container, the amount of light transmitted can be reduced to 1/3 or less, so light-shielding properties can be ensured not only in a bright room but also when left in sunlight for a long time. The most important effect of sealed packaging is that it not only ensures moisture resistance, gas barrier properties, waterproof properties, dust proof properties, heat proof properties, antistatic properties, etc. that are difficult to secure with light-shielding containers, but also maintains aesthetics and protects processing equipment and packaging materials. Lowering costs. Moreover, the quality of the strip-shaped photographic light-sensitive material can only be ensured by the combination of the light-shielding terremp cloth having the loop-shaped pile and a laminated film for sealed packaging with a moisture permeability of 10 g/m ² /24 hours or less.

As a result, light-shielding containers can be made of not only plastic containers but also very inexpensive paper (paperboard and corrugated paper).
It is possible to ensure sufficient strength and necessary characteristics even with a light-shielding box made of aluminum.

〔Example〕

An embodiment of the strip-shaped photographic material package of the present invention will be described below with reference to FIGS. 1 and 2.

FIG. 1 is a perspective view of a band-shaped photographic material package, and FIG. 2 is a partially cutaway perspective view of the same. In these figures, reference numeral 8 denotes a light-shielding container, and this light-shielding container 8 is hermetically packaged in a sealed bag 2 and kept airtight. The light-shielding container 8 is a strip-shaped photographic material support member 4
A core 3 is provided, and a band-shaped photographic material 1 is rotatably supported on this core 3. Further, as shown in the perspective view of the light-shielding container 8 with its upper part opened in FIG. 5 is attached. In addition, the code|symbol 9 is a heat seal part.

As shown in the enlarged cross-sectional view of FIG. 4 and the schematic cross-sectional view of FIG. 5, the light-shielding plush fabric 5 is made of loop-shaped pile yarns 1 woven together with ground yarns 12.
The surface of the knitted fabric is covered with a layer of 4. This is produced by first preparing a knitted fabric with pile yarn 14 woven into it, drawing out the pile yarn 14 in a loop shape using a raising machine equipped with needles, brushes, etc., and then heat setting the resulting fabric.

The sealed bag 2 is made of a laminated film as shown in the cross-sectional views of FIGS. 6 to 13.

The example shown in FIG. 6 is a laminated film in which a heat-sealing layer 18 is directly laminated on an aluminum vacuum-deposited thermoplastic resin film layer 17 in which an aluminum vacuum-deposited film layer 16 is formed on a thermoplastic resin film layer 15.

In the example of FIG. 7, the thermoplastic resin film layer 15 is inserted through the anchor coat layer 19 in the example of FIG.
This is a laminated film using an aluminum vacuum-deposited thermoplastic resin film layer 17 on which an aluminum vacuum-deposited film layer 16 is laminated.

The example shown in FIG. 8 is similar to the example shown in FIG. 6, with anchor coating applied between the thermoplastic resin film layer 15 and the aluminum vacuum-deposited film layer 16 and between the aluminum vacuum-deposited thermoplastic resin film layer 17 and the heat seal layer 18. This is a laminated film in which a layer 19 is provided and laminated.

The example shown in FIG. 9 is a laminated film in which an aluminum vacuum-deposited thermoplastic resin film layer 17 consisting of a thermoplastic resin film layer 15 and an aluminum vacuum-deposited film layer 16 and a heat-sealing layer 18 are laminated with an adhesive layer 20 interposed therebetween.

The example of FIG. 10 is an aluminum vacuum-deposited thermoplastic resin film layer 1 in which a thermoplastic resin film layer 15 and an aluminum vacuum-deposited film layer 16 are laminated via an anchor coat layer 19 in the example of FIG.
This is a laminated film using No. 7.

The example shown in FIG. 11 is a laminated film in which a flexible sheet layer 21 is laminated on the thermoplastic resin film layer 15 of the laminated film shown in FIG. 6 via an adhesive layer 20.

In the example shown in FIG. 12, the laminated film shown in FIG.
This is a laminated film in which flexible sheet layers 21 are laminated in the same manner as the example in FIG.

The example shown in FIG. 13 is a laminated film in which a flexible sheet layer 21 on which an anchor coat layer 19 is formed is laminated on the laminated film shown in FIG. 10 with an adhesive layer 20 interposed therebetween.

The moisture permeability of these sealing laminated films is as follows: When the thickness of the aluminum vacuum-deposited film layer is 400 Å, 5 g of calcium chloride is measured using the laminated film of the present invention.
When the material was placed in a 10 cm x 10 cm completely sealed room at 40°C and 90% RH for one day, the amount of moisture absorbed per m ² was determined to be less than 10 g/m ² for 24 hours. When the aluminum vacuum-deposited film was laminated without causing scratches or cracks, the moisture permeability measured by the above method was 3 g/m ² for 24 hours or less.

A particularly preferred example in terms of cost, heat sealability, appearance, physical strength, curl, moisture resistance, gas barrier properties, ease of opening, etc. is a sinker pile fabric with a knitted fabric structure as a light-shielding terempu cloth with looped piles. A vacuum-deposited aluminum film with a thickness of 300 to 500 Å was formed on a biaxially oriented polyester film with a thickness of 12 μm as shown in Figure 11 as a sealed bag. This is a package using a laminated film in which a heat-sealing layer mainly composed of high-density polyethylene resin is laminated, and a biaxially stretched polyester film with a thickness of 12 μm is laminated on the opposite side of the heat-sealing layer with a polyethylene adhesive layer.

Although the above embodiments are representative examples of preferred embodiments of the band-shaped photographic material package of the present invention, the present invention is not limited to the above, and it is possible to use other known materials and flexible sheet layers. Combinations are possible.

[Effect of idea]

In the band-shaped photographic material package of the present invention, the light-shielding container is hermetically sealed in a sealed bag, so it can completely ensure the moisture-proofing, gas-barrier, dust-proofing, and heat-proofing properties that were insufficient with the light-shielding container alone. In addition, it is possible to completely ensure light-shielding properties that were insufficient under sunlight.
Furthermore, since the light-shielding container can be protected from impact and the sealed bag can ensure moisture resistance, light-shielding properties, etc., the structure of the light-shielding container and the light-shielding terem cloth can be easily made, and the light-shielding container having a loop-shaped pile can be formed from paper. It is also suitable for manufacturing and processing packages, and is inexpensive, allowing for significant cost reductions.

[Brief explanation of the drawing]

FIG. 1 is a perspective view of a band-shaped photographic material package of the present invention, FIG. 2 is a partially cut away perspective view of the same, and FIG. 3 is a perspective view of the light-shielding container shown above with its upper portion opened. FIG. 4 is an enlarged sectional view of a light-shielding terempu cloth having loop-shaped piles, and FIG. 5 is a schematic sectional view of the same. 6 to 13 are cross-sectional views of the laminated film used for the sealed bag. Figure 14 and 1
FIG. 5 is a perspective view of a conventional package. 1... Band-shaped photographic material, 2... Sealed bag, 3...
...core, 4...band-shaped photographic material support member, 5...
...Light-shielding terempu cloth with looped pile, 8...
... light-shielding container, 11 ... adhesive for fixing loop-shaped pile, 12 ... ground thread, 14 ... loop-form pile thread, 15 ... thermoplastic resin film layer, thickness
55-1200 Å aluminum vacuum-deposited film layer, 17...
... Aluminum vacuum vapor deposited thermoplastic resin film layer, 18 ... Heat seal layer, 19 ... Anchor coat layer, 20 ... Adhesive layer, 21 ... Flexible sheet layer.

Claims (1)

[Claims for Utility Model Registration] (1) A core that rotatably supports a strip of photographic light-sensitive material wound into a roll, and loop-shaped piles provided above and below the longitudinal side of a drawer opening from which the strip of photographic light-sensitive material is pulled out. A light-shielding container with a light-shielding thermoplastic resin film layer having a thickness of 55 to 1200 Å, and a heat-sealing layer laminated directly or via an adhesive layer on the aluminum vacuum-deposited thermoplastic resin film layer with a thickness of 55 to 1200 Å. 10g/ ^m2・
A strip-shaped photographic material package (2) comprising a sealed bag in which the light-shielding container is sealed with a laminated film that lasts for 24 hours or less. Utility model registration claim 1 which is a laminated film in which a flexible sheet layer having a heat resistance higher than that of the heat seal layer is provided directly or via an adhesive layer on the opposite side of the heat seal layer.
Band-shaped photographic material package (3) according to claim 1 or 2, wherein the aluminum vacuum-deposited thermoplastic resin film layer is a biaxially stretched film having a thickness of 10 to 40 μm. Strip-shaped photographic light-sensitive material package (4) The strip-shaped photographic light-sensitive material package according to claim 1, 2, or 3 of the utility model registration claim, wherein the sealed bag has a silver appearance.