JP5736283B2 - Rust-proof laminated film - Google Patents

Description

  The present invention relates to rust prevention of metals, and more particularly, to a rust prevention laminated film for packaging used to suppress rusting during storage or transportation of metal machines and parts.

  In general, rust-proof packaging is performed in order to prevent the surfaces of machines and parts from being oxidized and rusting during storage and transportation of metal machines and parts. JIS Z-0303 (General Rules for Rust Prevention Packaging Method) defines a rust prevention packaging method and is widely used for rust prevention management. These general rules stipulate rust-preventing oil and rust-preventing agents (vaporizable, water-soluble, water-soluble water-soluble) as rust-proofing materials. Others are prescribed.

  Since rust prevention oil is performed by immersing a metal product in rust prevention oil, the rust prevention oil penetrates into the details of the metal product and has a high rust prevention effect. However, after removing the metal product from the rust-preventing oil, it must be drained for about 24 hours, and after storage and transportation, the rust-preventing oil must be washed before use. It took a lot of time and cost. In addition, since a fluorocarbon-based cleaning agent is used as a cleaning agent, there are problems in global environmental conservation, and there is a problem in the processing of the washed rust prevention oil.

  Therefore, in recent years, a vaporizable rust preventive agent (hereinafter referred to as “vaporizable rust preventive agent”) that does not have the above-described problems and has an advantage of entering even the details of metal products has been used. Vaporizable rust preventives are those that vaporize (sublimate) at room temperature to enter the details of metal products and exhibit rust prevention effects. As such vaporizable rust preventives, nitrite is mainly used for steel. (Refer to Patent Document 1 etc.) and those mainly composed of amines (refer to Patent Document 2 etc.), and there are heterocyclic compounds such as triazole rings for copper. These vaporizable rust preventives are It is sold by each company.

  Such vaporizable rust preventives can be used by spraying the vaporizable rust preventive agent directly into the package, packing it in a gas-permeable bag and storing it in the package, or using a vaporizable rust preventive agent. Applying or impregnating paper to produce rust-proof paper, wrapping metal products with this rust-proof paper, or attaching rust-proof film containing vaporizable rust-proofing agent to paperboard to produce rust-proof paperboard And make a packing box with this rust-proof paperboard, and pack and seal metal products (see Patent Document 3 etc.), or from two components of vaporizable rust inhibitor and low melting point resin (ethylene-vinyl acetate copolymer resin) There has been proposed a method in which a bag is made of a film obtained by laminating a uniform mixed composition formed on a base film of a high melting point resin, and a metal product is stored in the rust-proof bag (see Patent Document 4).

WO2005 / 068559 JP 2006-169627 A JP-A-6-48460 JP 49-1644 A

  However, the vaporizable rust preventive agent can be sprayed directly into the package, packed in a gas permeable bag and stored in the package, or wrapped with rust preventive paper coated or impregnated with the vaporizable rust preventive agent In the method, the vaporized gas of the vaporizable rust preventive agent can easily escape to the outside of the package, and since the effect is lost when all of the vaporizable rust preventive agent is vaporized, the durability of the rust preventive effect is short. Further, in the method using a packaging box made of rustproof paperboard, since the paperboard is porous, the vaporized rustproofing agent easily escapes from the packaging box and has a short duration of effect.

  Furthermore, in a method of storing metal products in a rust-proof bag made of a film in which a uniform mixture composition of a vaporizable rust inhibitor and a low-melting resin is laminated on a base film of a high-melting resin, polyethylene is used as the base film. Since a film, a polypropylene film, a polyester film, a nylon film, or the like was used alone, the vaporized rust preventive agent was easily transmitted, and the durability of the rust preventive effect was short.

  In particular, in recent years, the rust-prevention period required for metal products is as long as several months at room temperature and one month under the conditions of the hold (50 ° C inside and outside, high humidity) just below the equator when transporting overseas. It was desired and could not satisfy such a request.

  An object of the present invention is to provide a rust-proof laminated film that solves the above-described problems and can maintain a rust-proofing effect for a long period of time.

  As a result of diligent research, the present inventors have found that a biaxially stretched nylon film (hereinafter referred to as “O-NY film”) that does not generate pinholes and a polyvinylidene chloride (hereinafter referred to as “PVDC”) having excellent gas barrier properties. PVDC coated O-NY film coated with a rust preventive film of LDPE resin or LLDPE resin kneaded with a vaporizable rust preventive agent, and the metal product is stored with the rust preventive film inside. It is found that the gas of the vaporizable rust inhibitor vaporized from the rust film is blocked by the PVDC coat layer, stays in the bag without escaping to the outside, and can exhibit the rust preventive effect over a long period of time, thereby completing the present invention. It came to.

The rust-proof laminated film according to claim 1 includes a PVDC-coated O-NY film obtained by coating PDC on an O-NY film, and a rust-proof film obtained by kneading a vaporizable rust-proofing agent. The coated O-NY film is laminated with a dry laminate on the PVDC coated surface, and the adhesive of the dry laminate is a two-component curing type adhesive of a polyether type main agent and an isocyanate curing agent. The rust film is characterized in that a rust preventive agent is kneaded with LDPE resin or LLDPE resin and is formed into a film by an inflation method.

  In the rust-proof laminated film according to claim 1, the O-NY film is strong against stagnation and hardly generates pinholes, and the PVDC coating layer is excellent in bath barrier properties and pinholes are strong against stagnation. Furthermore, since the adhesive strength between the O-NY film and the PVDC coating layer is high, the PVDC coating layer is not peeled off from the O-NY film. The rust preventive film is one in which the kneaded vaporizable rust preventive agent is vaporized and diffuses to the outside of the rust preventive film.

  Therefore, when the rust preventive film is disposed on the inner surface and the bag is produced and hermetically packaged, the rust preventive agent vaporized inside the bag can be retained for a long period of time. That is, the vaporizable rust preventive agent kneaded in the rust preventive film evaporates over time and permeates the rust preventive film, so that it is vaporizable on the inner surface side of the rust preventive film (the inner surface side of the bag). The rust preventive agent diffuses and fills the inside of the bag, but on the outer surface side of the rust film (the outer surface side of the bag), since the PVDC coat layer is laminated, the vaporized rust preventive agent is the PVDC coat. Blocked by layers. Therefore, the vaporized rust preventive agent accumulates only inside the bag, and the gap between the vaporizable rust preventive agent kneaded in the rust preventive film and the gas inside the bag. When the is in an equilibrium state, the vaporizable rust preventive solid does not vaporize. As a result, as long as this equilibrium state is not broken, vaporization of the kneaded vaporizable rust inhibitor is suppressed, and a rust preventive effect can be exhibited over a long period of time.

  Also, even if bags are squeezed in the distribution process or bent in the packaging process (vacuum packaging, etc.), no pinholes are generated in the O-NY film and the PVDC coating layer. There is no peeling from the O-NY film. Therefore, the vaporizable rust preventive agent filled in the bag can be stably held even when exposed to a severe state by external pressure or the like.

  Further, since the rust-proof film and the PVDC-coated O-NY film are laminated by dry lamination, it is the most commonly used film lamination method, and can be easily and inexpensively laminated.

Moreover, since the rust prevention film is formed by the inflation method using LDPE resin or LLDPE resin, it can be formed at a low temperature. Therefore, the vaporization of the kneaded vaporizable rust inhibitor is small during film formation, and most of the vaporizable rust inhibitor can remain in the rust film.

Furthermore, in such a rust-proof laminated film, a two-component curable adhesive consisting of a polyether-based main agent and an isocyanate curing agent is used as an adhesive for dry lamination, so rust is generated from the adhesive. No substances are generated. Therefore, the rust preventive hardening of the rust preventive agent can be sufficiently exhibited.

Diagram showing changes in gas barrier properties The figure which shows the humidity dependence of the oxygen permeation amount of EVOH film

  The rust-proof laminated film of the present invention is a laminate of a PVDC-coated O-NY film obtained by coating PVDC on an O-NY film and a rust-proof film obtained by kneading a vaporizable rust preventive agent. This prevents rust of metal products.

  Most metals exist as a compound except gold. For example, iron is produced as iron ores such as magnetite and limonite, and is refined by a blast furnace or the like to obtain iron. This iron state is a metastable state and proceeds towards the original oxidized stable state. It is believed that oxidation in air proceeds according to the reaction formula shown in Chemical Formula 1.

  As is apparent from this reaction equation, water and oxygen can be excluded to protect iron from oxidation in the air. Therefore, the rust prevention method of immersing a metal product in rust prevention oil is a rust prevention method in which the surface of the metal is covered with a coating of rust prevention oil and moisture and oxygen in the air are blocked to prevent oxidation.

  On the other hand, there are vaporizable rust preventives as rust preventives. For iron, nitrites of amines, carboxylates of amines, chromates of amines, esters of carboxylic acids, and mixtures thereof Etc. For copper and copper alloys, there are a heterocyclic compound such as a triazole ring, a pyrrole ring, a pyrazole ring, a thiazole ring, an imidazole ring, a thiourea, or a mercapto group. In the case of nitrites of amines for iron, the rust prevention mechanism of these vaporizable rust preventives is, for example, that vaporized dicyclohexylammonium nitrite dissolves in moisture adsorbed on the iron surface and reacts with iron. Rust prevention is achieved by creating a stable film (see Chemical Formula 2).

  In the case of amine carboxylates, the gas vaporized in the water adsorbed on the metal surface dissolves, dissociates into amine and carboxylic acid in the water, and recombines on the metal surface to form a stable amine carboxylate. It is thought to create an acid film and prevent rusting (see Chemical Formula 3).

  Furthermore, in the case of benzotriazole for copper, it is thought that gas vaporized by moisture adsorbed on the metal surface dissolves and reacts with copper to form a stable benzotriazole copper salt film to prevent rusting. 4).

  Vaporizable rust preventives to be kneaded into rust preventive films are mainly vaporized rust preventives for iron if the metal product to be rusted is iron products, and vaporized rust preventive for copper if it is a copper or copper alloy product. Can be mixed and kneaded if necessary.

  The kneading amount of the vaporizable rust inhibitor is appropriately set optimally depending on the characteristics (vaporization rate, rust prevention effect) of the vaporizable rust inhibitor, the required rust prevention period, the film forming method, the packaging form, and the like. For example, if the vaporization rate is high, the amount of vaporization disappears during film formation of the rust-preventive film, so it is necessary to knead a lot.If the rust-prevention effect is small, a large amount of kneading is performed to obtain a predetermined rust-prevention effect. In the case of a film forming method having a high temperature during film formation, it is necessary to knead a lot in order to compensate for the loss. As described above, various conditions are examined and an appropriate kneading amount is appropriately set.

  In consideration of the above conditions, the kneading amount of the vaporizable rust preventive agent is preferably 0.5 to 5% by weight, preferably 1.0 to 3.0% when the metal product is stored at 20 ° C.-60% RH for 3 years. % Is more preferable. If the kneading amount is less than 0.5% by weight, if the vaporization rate is high, the vaporization disappears during film formation, and if the rust prevention effect is small, a sufficient rust prevention effect cannot be expected. On the other hand, if it exceeds 5% by weight, a sufficient rust prevention effect can be obtained, but the cost becomes high.

  The vaporizable rust preventive as described above is directly vaporized (sublimated) from a solid at room temperature without passing through a liquid, and its vaporization rate increases as the temperature increases. Therefore, when a rust-preventive film is formed by kneading with a resin, it is necessary to form the film at a temperature as low as possible. Therefore, although there are a T-die method and an inflation method for film formation, the inflation method is preferable because it can be formed at a low temperature.

Moreover, since it can form into a film at low temperature, resin with low melting | fusing point is preferable, for example, LDPE resin and LLDPE resin are preferable. In the film formation by the inflation method of LDPE resin or LLDPE resin, the film can be formed at a low temperature of 150 to 200 ° C. Further, these resins preferably have better melt tension is large, e.g., MFR is preferably in the range of 0.1-5 g / 10 min, and more preferably in a range of from 0.5 to 3 g / 10 min. MFR is is less than 0.1 g / 10 min, extrusion becomes difficult under stress subscription-menu of the extruder, also exceeds 5 g / 10 min, and unstable bubble melt tension was blown up small Thus, a uniform thickness cannot be obtained.

  20-150 micrometers is preferable and, as for the thickness of a rust prevention film, 30-120 micrometers is more preferable. When the thickness is less than 20 μm, it is difficult to form a film by the inflation method, and when it exceeds 150 μm, the cost increases.

  The PVDC-coated O-NY film is extremely resistant to stagnation, and pinholes do not occur when the film is bent or entrapped in a physical distribution process or a vacuum packaging process. A test comparing the resistance against stagnation between the PVDC-coated O-NY film and the deposited film of SiOx will be described. Each film was evaluated by changes in oxygen gas barrier properties and water vapor barrier properties before and after the gelboflex test. The tested films are as follows.

O-NY / PVDC (coat) / dry / LLDPE (50 μm)
O-NY / SiOx (deposition) / dry / LLDPE (50 μm)
PET / SiOx (deposition) / dry / LLDPE (50 μm)
The results are shown in FIG. From the results of FIG. 1, it can be seen that O-NY / PVDC (coat) / dry / LLDPE (50 μm) hardly deteriorates in oxygen gas barrier property and water vapor barrier property even after 100 gelbo tests. On the other hand, PET / SiOx (deposition) / dry / LLDPE (50 μm) and O-NY / SiOx (deposition) / dry / LLDPE (50 μm) have oxygen gas barrier properties and water vapor after 100 gelbo flex tests. It can be seen that the barrier properties are also greatly reduced. This is because the deposited SiOx layer is cracked by stagnation, and oxygen gas and water vapor easily pass through. Therefore, it turns out that the laminated | multilayer film which has a vapor deposition SiOx layer cannot be used for a rust prevention laminated | multilayer film.

  Regarding the oxygen gas barrier property, the oxygen permeability measuring device (“OX-TRAN (registered trademark) MODEL 2/21” manufactured by MOCON) was used under the conditions of a temperature of 20 ° C. and a humidity of 70% RH. Was measured under the conditions of a temperature of 40 ° C. and a humidity of 90% RH using a water vapor permeability meter (“OX-TRAN (registered trademark) MODEL 3/33” manufactured by MOCON).

  In addition, EVOH film is known as a film having excellent oxygen gas barrier properties. However, the oxygen gas barrier property is dependent on humidity, and when the humidity exceeds 60%, the performance rapidly increases as shown in FIG. The gas barrier function is lost under high humidity. Further, the water vapor barrier property is the worst among plastic films, and there is no water vapor blocking performance. Therefore, the EVOH film cannot be used for the rust-proof laminated film of the present invention. On the other hand, the PVDC coating layer does not depend on humidity in the gas barrier property, and maintains a stable gas barrier property without decreasing both the oxygen gas barrier property and the water vapor barrier property even under high humidity. .

  The rust-proof laminated film of the present invention is obtained by laminating the above-mentioned rust-proof film on the PVDC-coated surface of the PVDC-coated O-NY film by dry lamination. Adhesives used for dry lamination include two-part curable adhesives composed of a polyether-based main component and an isocyanate curing agent, and two-part curable adhesives composed of a polyester-based main component and an isocyanate curing agent. is there.

  Typical polyethers include polyethylene glycol and polypropylene glycol made by ring-opening polymerization of ethylene oxide and propylene oxide. Typical polyesters include those made by dehydration condensation reaction from polyhydric alcohols such as ethylene glycol and 1.6 hexanediol and polycarboxylic acids such as terephthalic acid, isophthalic acid and adipic acid, Particularly representative is polyethylene terephthalate made from ethylene glycol and terephthalic acid. As these two types of main curing agents, there are isophorone diisocyanate (IPDI), hexamethylene diisocyanate (HDI), and toluene diisocyanate (TDI).

  Of these, a two-component curable adhesive comprising a polyester-based main agent and an isocyanate curing agent impairs the rust prevention effect and causes rusting. That is, unreacted polyvalent carboxylic acid in the dehydration condensation reaction remains in the production process of the polyester produced by the dehydration condensation reaction from the polyhydric alcohol and the polyvalent carboxylic acid. It is thought that this is because it passes through the rust-proof film and moves to the inner surface of the bag. Therefore, the two-component curable adhesive comprising a polyester-based main agent and an isocyanate curing agent cannot be used for the rust-proof laminated film of the present invention (see Table 4).

  On the other hand, a two-component curable adhesive comprising a polyether-based main component and an isocyanate curing agent does not have the above-described adverse effects, and is suitable for the rust-proof laminated film of the present invention.

  The rust-proof laminated film of the present invention is used by forming a rust-proof film surface on the inner surface side and a PVDC-coated O-NY film on the outer side to form a bag, and housing and sealing the metal product in this bag. By using in this way, the gas of the vaporizable rust inhibitor evaporated from the rust preventive film is filled in the bag, so that the metal product can exhibit a rust preventive effect. Moreover, it can be widely used in the field | area where the antirust effect is calculated | required besides a bag shape.

[Example 1]
[Production of vaporizable rust inhibitor masterbatch]
After mixing and reacting 2 mol of KOH in the presence of water with respect to 1 mol of sebacic acid (“HOKOKU-SA” manufactured by Toyokuni Oil Co., Ltd.), the moisture content is evaporated and dried by a spray drying method. A crystal of potassium sebacate having a concentration of 5% or less was obtained. After mixing this potassium sebacate and benzotriazole ("CV I.TT" manufactured by Kyrest Co., Ltd.) at a ratio of 80 parts by weight: 20 parts by weight, the mixture is pulverized to 100 μm or less by a pulverizer and vaporized. A mixed composition of an anticorrosive agent was obtained. This mixed composition and LLDPE resin (“SP2020” manufactured by Prime Polymer Co., Ltd.) are charged into an extruder equipped with a pelletizer at a ratio of 30 parts by weight to 70 parts by weight, extruded at an extrusion temperature of 150 ° C., and pelletized. A vaporizable rust preventive masterbatch (hereinafter referred to as “vaporizable rust preventive MB”) containing 30% by weight of a vaporizable rust preventive was prepared.

[Production of rust-proof film]
5 parts by weight: 95 parts by weight of the vaporizable rust preventive MB and LLDPE resin (“SP2020” (MFR: 2.3 g / 10 min, density: 0.915 g / cm ³ ) manufactured by Prime Polymer Co., Ltd.) Dry blended at a ratio and mixed. This mixed resin was put into an air-cooled inflation film forming machine, and inflation film formation was performed under the following conditions. The obtained inflation film (rust preventive film) had a vaporizable rust preventive agent content of 1.5% by weight and a thickness of 70 μm.

Cylinder diameter: 65mmΦ, L / D; 25
Round die diameter: 200mmΦ
Lip cap: 0.8mm
Extrusion temperature: 160 ° C
Blow ratio: 2.5
Cooling air: 15 ° C., flow rate: 20 m ³ / min
Film forming speed: 10 m / min

[Preparation of rust-proof laminated film]
A PVDC-coated O-NY film (“Emblem DCWU” (thickness: 15 μm) manufactured by Unitika Ltd.) was prepared, and the PVDC-coated surface of this PVDC-coated O-NY film was subjected to a corona treatment of 50 W · min / m ² . . Next, a gravure roll with 95 screen lines by helio engraving was set on a dry laminating machine (“LX-3” manufactured by Nakajima Seiki Engineering Co., Ltd.), and a polyether-based adhesive (adhesive manufactured by Rock Paint Co., Ltd.) Main agent: RU-3600, curing agent: H-689, solvent: ethyl acetate)) was applied to the PVDC coated surface at a processing speed of 100 m / min and dried in three zones of hot air temperature 60 ° C, 80 ° C, 75 ° C. I let you.

Next, the rust-proof film is subjected to corona treatment at 50 W · min / m ² , the corona-treated surface is aligned with the adhesive-coated surface of the PVDC-coated O-NY film, and a nip pressure of 18 kg-cm is applied. Then, aging was performed in an aging chamber at 50 ° C. for 3 days to produce a rust-proof laminated film.

[Lamination strength test]
After cutting the rust-proof laminated film to a width of 15 mm, the bonded part is peeled off by hand, and both peeled parts (PVDC-coated O-NY film and rust-proof film) are fixed to the chuck of a constant-speed tensile tester. Then, the gap between the initial chucks is set to 50 mm, and 300 mm / min. T-type peeling was carried out while keeping the unpeeled portion horizontal at a tensile speed of 1, and the laminate strength between the PVDC coat layer and the rust preventive film layer of the PVDC coat O-NY film was measured. The results are shown in Table 1.

  The laminate strength was sufficient as a packaging material.

[Gas barrier property test]
Regarding the gas barrier property of the rust-proof film and the oxygen gas barrier property, an oxygen permeability measuring device (“OX-TRAN (registered trademark) MODEL 2/21” manufactured by MOCON) was used, and the temperature was 30 ° C. and the humidity was 80% RH. The water vapor barrier property was measured under the conditions of a temperature of 40 ° C. and a humidity of 90% RH using a water vapor transmission meter (“OX-TRAN (registered trademark) MODEL 3/33” manufactured by MOCON). The results are shown in Table 2.

  Both oxygen gas barrier properties and water vapor barrier properties are sufficient as packaging materials, and in particular, water vapor barrier properties allow water vapor to permeate and penetrate even at high temperatures and high humidity in the hold just below the equator during export. It is not considered.

[Comparative Example 1]
It consists only of the rust-proof film used for the rust-proof laminated film of Example 1.

[Comparative Example 2]
Except not knead | mixing a vaporizable rust preventive agent, it consists only of the LLDPE film produced on the same conditions as the rust preventive film of Example 1. FIG.

[Rust prevention test]
SP240 (cold rolled steel plate: 60 × 80 × 1.2 mm), C1100P (tough pitch copper plate: 40 × 60 × 1.2 mm) and zinc plate (formerly 2 types: 40 × 60 × 1.2 mm) # 240 polished paper After polishing, the sample was prepared by degreasing. Further, the films of Example 1, Comparative Example 1 and Comparative Example 2 were cut into rectangles, and in Example 1, the three sides were heat-sealed so that the rust-proof film surface was the inner surface, and the inner dimension was 90 × 110 mm and the inner Two types of bags each having a size of 70 × 90 mm were prepared.

  The test piece of SPCC is housed in a bag with an inner dimension of 90 × 110 mm, the test piece of C1100P and the zinc plate is housed in a bag with an inner dimension of 70 × 90 mm, and the aerated packaging (the test piece is placed on the inner surface of the bag). Two types of packaging were performed: air was left so as not to contact) and vacuum packaging (air was sucked so that the test piece was in contact with the inner surface of the bag).

  The rust prevention test of the test piece which carried out these packaging was performed using the environmental testing machine ("Silbury Emperor" made by KATO). The temperature and humidity conditions of the environmental tester are (5 ° C / 95% RH-6 hours → 50 ° C / 95% RH-16 hours) as one cycle, and the surface of the test piece is visually observed while repeating this cycle. The discoloration state was evaluated. The results are shown in Table 3.

Evaluation is as follows.
◎: Corrosion, rust, no discoloration ○: Slight corrosion (1 to 3 spot rust, discoloration area less than 10%)
Δ: Mild corrosion (4-9 spot rust, discoloration area less than 10-30%)
X: Clear corrosion (10 or more spot rust, discoloration area 30 to less than 50%)
XX: Severe corrosion (discolored area 50% or more)

  As can be seen from the results in Table 3, Example 1 has a much longer antirust effect than Comparative Example 1 with only an anticorrosive film, and can be stored for 3 years or more at 20 ° C.-60% RH. It is.

  This is because the rust preventive agent vaporized in the bag passes through the LLDPE layer and escapes to the outside with the rust preventive film alone, whereas the vaporizable rust preventive agent kneaded in the LLDPE layer disappears quickly. In the invention, the rust preventive agent vaporized in the bag is blocked by the PVDC coating layer, and the rust preventive agent vaporized in the bag and the solid rust preventive agent kneaded in the LLDPE layer are balanced and kneaded. This is because vaporization of the applied antirust agent (solid) is suppressed.

[Comparative Example 3]
As an adhesive used when bonding a PVDC coat O-NY film and a rust preventive film with a dry laminate, a polyester-based adhesive (an adhesive manufactured by Rock Paint Co., Ltd. (main agent: RU-80, curing agent: H -5, Solvent: Acetic acid ethyl ester)) was used, and a laminated film was prepared in exactly the same process using the same material as in Example 1.

[Comparative Example 4]
Except not knead | mixing a vaporizable rust preventive agent, it consists only of the LLDPE film produced on the same conditions as the rust preventive film of Example 1. FIG.

[Rust prevention test]
As in the case of Example 1, SPCC and C1100P test pieces were prepared, bags of two sizes were prepared, aerated packaging and vacuum packaging were performed, and an environmental tester (“Silverly Emperor” manufactured by KATO) was used. )) Under the same conditions, and the rust, corrosion, and discoloration of the surface of the test piece were evaluated. The evaluation criteria are the same. Table 4 shows the results of the rust prevention test.

  From the results of the SPCC section, although Comparative Example 3 is laminated with a rust-proof film, rust is generated faster than Comparative Example 4, and the film is a test piece when compared with aerated packaging and vacuum packaging. It was confirmed that the rust was generated earlier in the vacuum packaging in contact with From this result, it is considered that Comparative Example 3 has a factor that promotes the generation of rust. Since such a phenomenon does not occur in the polyether-based adhesive of Example 1, it is considered that it is derived from the polyester-based adhesive. That is, in the production process of the main component of the polyester-based adhesive, the polyvalent carboxylic acid, which is an unreacted product of the dehydration condensation reaction between the polyhydric alcohol and the polyvalent carboxylic acid, remains, and a large amount is obtained from the adhesive layer bonded by dry lamination. It is considered that the monovalent carboxylic acid passes through the rust-proof film and moves into the bag, adheres to the surface of the test piece, and promotes the generation of rust.

Claims (1)

It has a PVDC-coated O-NY film in which PVDC is coated on an O-NY film, and a rust-preventing film in which a vaporizable rust inhibitor is kneaded, and the rust-preventing film is dried on the PVDC-coated surface of the PVDC-coated O-NY film. The dry laminate adhesive is a two-component curable adhesive composed of a polyether-type main agent and an isocyanate curing agent, and the rust-preventing film is protected against the LDPE resin or LLDPE resin. A rust-preventing laminated film obtained by kneading a rusting agent and forming a film by an inflation method.

Images