JP2005088549A - Method for producing oxygen-absorptive multi-layer film - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an oxygen-absorptive multi-layer film in which degradation of adhesion to the adjacent layer or of heat-sealing ability of an oxygen-permeable resin layer by forming on the surface layer a rough surface of a deoxygenizing fine particles in the oxygen-absorbtive resin layer can be prevented or projection of the deoxygenizing fine particles from the oxygen-permeable resin layer can be prevented. <P>SOLUTION: The first production method: a cushioning resin layer is laminated by extrusion to an oxygen-blocking outer layer film to be introduced, then an oxygen-absorptive resin layer is laminated by extrusion between the cushioning resin layer and the oxygen-permeable resin layer. The second production method: a cushioning resin layer and an oxygen-absorptive resin layer are laminated by co-extrusion between the oxygen-blocking outer layer film and the oxygen-permeable resin film, the both being introduced together. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a method for producing an oxygen-absorbing multilayer film, and more particularly, an oxygen-containing outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer. The present invention relates to an improvement in a method for producing a multilayer film excellent in absorption and oxygen shielding properties by extrusion lamination molding.

  In recent daily necessities containers, plastic containers are widely used from the viewpoints of lightness, economy, moldability, physical properties, etc., and are indispensable in various applications such as food and medicine. Compared to metal cans and glass bottles, plastic has a small amount of gas permeability, so in the case of plastic containers, oxygen intrusion through the vessel wall cannot be ignored. There has been a problem in terms of the storage stability of the stored contents by chemically changing the contents or by promoting the growth of microorganisms in which oxygen causes spoilage in the container. In addition, oxygen present in the container with the stored contents has caused the same problem.

As a method for dealing with such problems, in order to prevent oxygen intrusion through the wall of the plastic container, the container wall has a multi-layer structure, and at least one layer thereof has an oxygen shielding property such as an ethylene-vinyl alcohol copolymer. In order to remove oxygen in the container, an oxygen scavenger is also used to absorb the oxygen in the container by the oxygen scavenger present in the container wall. The above problem was basically solved by the development of a container for maintaining the inside in a highly oxygen-free state.
As an example of a typical improved container, a layer having an oxygen barrier property and a layer formed by blending a resin having oxygen permeability with a deoxidizing agent containing a reducing substance as a main component are laminated to provide an external coating. Multi-layered containers that prevent oxygen from entering and absorb internal oxygen have been used for a long time.
Such a plastic container is a very excellent container that prevents oxygen from entering from the outside through the vessel wall, absorbs and deoxygenates oxygen inside the container, and enhances the storage stability of the contents. Many improvements have been made in the layer structure of the vessel wall, the resin material forming the layer, the oxygen absorbent, the method of forming the multilayer structure, and the like.

  However, in such an oxygen-absorbing multi-layer container that is very excellent in content preservation with respect to oxygen, there still remains a problem that has not been sufficiently solved, and this is a reduction in the oxygen-absorbing resin layer. Oxygen scavenger fine particles such as porous metal fine particles produce fine irregularities on the layer surface, degrading the bondability with the adjacent oxygen shielding layer and the heat sealability of the oxygen permeable resin layer, or the oxygen permeable resin layer There is a strong demand for a solution to the problem in oxygen-absorbing multilayer containers, because oxygen scavenger fine particles protrude from or are exposed from the layer surface and contaminate the contents contained in the container.

As a technique for solving such a new problem, a solution means for forming a cushioning resin layer between the oxygen shielding layer and the oxygen-absorbing resin layer is disclosed (see Patent Document 1), and the oxygen-absorbing property is obtained by oxygen absorber fine particles. This cushion layer absorbs minute irregularities generated on the layer surface of the resin layer, thereby preventing the deterioration of the interlayer bonding property.
This method of adopting the cushion layer is further developed in the oxygen-absorbing multilayer film material used as the material of the multilayer container, and regulates the diameter of the oxygen scavenger fine particles so that the maximum diameter of the oxygen scavenger fine particles is reduced. Multilayer film (see Patent Document 2) that is less than the sum of the thickness of the absorbent resin layer and the smoothing layer (cushion layer), the oxygen-shielding outer layer, the thermoplastic resin cushion layer (smoothing layer), and the oxygen-absorbing property As a method for producing a multilayer film comprising a thermoplastic resin layer and an oxygen permeable thermoplastic resin inner layer by lamination molding, each layer is formed by combining extrusion and lamination, and a cooling roll is formed on the outer surface side of the oxygen permeable resin layer. Method of making multilayer film in close contact and cooling (see Patent Document 3), thermoplastic resin cushion layer, oxygen-absorbing thermoplastic resin layer, and oxygen-permeable thermoplastic resin A multilayer material in which each base material of the layer is a low density polyethylene resin, and the density of the base material of the cushion layer and the inner layer of the thermoplastic resin is larger than the density of the base material of the oxygen absorbing layer (see Patent Document 4), oxygen shielding properties As a method for producing a multilayer film comprising an outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer by laminating, oxygen is interposed between the cushion layer and the thermoplastic resin inner layer. A production method of a multilayer film (see Patent Document 5) in which an absorbent resin layer is extruded and laminated, a cooling roll is brought into close contact with the outer surface side of the outer layer, and cooled is disclosed as a series of development improvement techniques.

Japanese Patent Laid-Open No. 9-40024 (Claim 1, Claim 0015) JP 11-254603 A (summary) Japanese Patent No. 2967740 (claims 1 to 6 and paragraphs 0019 to 0020) JP 2002-1888 (abstract, claims 1 to 2 in claims) JP 2002-307536 A (claims 1-2, paragraph 0019)

As described above in paragraph 0004, the oxygen-absorbing fine particles such as reducing metal fine particles in the oxygen-absorbing resin layer, which is an important problem in the oxygen-absorbing multi-layer container, cause fine irregularities on the layer surface, and adjacent to each other. This deteriorates the bondability with the oxygen shielding layer and the heat sealability of the oxygen permeable resin layer, or the oxygen scavenger fine particles protrude or are exposed from the layer surface of the oxygen permeable resin layer to contaminate the contents contained in the container. As described in Paragraph 0005, a series of improved technologies have been developed, and considerable improvement results can be obtained. However, in any of these technologies, the oxygen scavenger fine particles are formed on the layer surface. The adhesion between the oxygen-absorbing resin layer and the adjacent cushion layer, as well as the adhesion between the oxygen-shielding layer and the heat-sealability of the oxygen-permeable resin layer due to minute irregularities through the cushion layer. Or the oxygen scavenger fine particles projecting or exposed from the layer surface of the oxygen permeable resin layer and contaminating the contents contained in the container is still difficult to prevent, especially, Even if the cushion layer is not provided on the oxygen permeable resin layer side, it seems difficult to completely prevent the oxygen absorber fine particles from protruding or exposed from the layer surface of the oxygen permeable resin layer.
Further, in the technique of Patent Document 2, it is inevitable that the definition of the oxygen scavenger fine particles is complicated and the particle diameter and the thickness of the oxygen-absorbing resin layer and the cushion layer are limited. Since the cooling roll is sometimes brought into close contact with the outer surface side of the oxygen permeable resin layer that becomes the inner layer of the film and cooled, the smoothness of the outer layer surface side of the multilayer film is lowered. Although there is a recognition that the shielding pigment in the porous resin layer prevents the oxygen scavenger fine particles from sticking to the outer surface of the inner layer, it is a technology whose main aim is to improve tearability as a laminated packaging material. In the technique of No. 5, since the cooling roll is brought into close contact with the outer surface side of the oxygen shielding layer which is the outer layer of the film when the films are laminated and cooled, the smoothness on the inner layer surface side of the multilayer film is somewhat low. It is difficult to avoid.

  The present invention is based on such a technical situation, and in the oxygen-absorbing multilayer container, the oxygen-absorbing multilayer film is also an important problem. A fine uneven surface is formed, and the adjoining cushion layer and the minute unevenness through the cushion layer deteriorate the bonding property with the oxygen shielding layer and the heat sealability of the oxygen permeable resin layer, or from the layer surface of the oxygen permeable resin layer The problem to be solved by the present invention is that the problem that the oxygen scavenger fine particles protrude or are exposed to contaminate the contents contained in the container is sufficiently solved by simple means in all the layers of the multilayer film. To do.

  The inventors of the present invention have described that the oxygen scavenger fine particles in the multilayer film protrude from the oxygen-absorbing resin layer to the outside of the layer, and the bonding property and oxygen permeability with the adjacent cushion layer or oxygen shielding layer. Aiming to solve the problems of the invention by sufficiently preventing the deterioration of the heat sealability of the resin layer and the protrusion and exposure of the oxygen scavenger fine particles from the layer surface of the oxygen permeable resin layer. In consideration of the prior art represented by ~ 5, it is effective for the overall structure of each layer of the oxygen-absorbing multilayer film, including the layer structure, the resin material that forms the layer, the oxygen absorbent, and the method of forming the multilayer. We searched for a solution to the problem.

  Then, in the process of considering the layer structure, the resin material forming the layer, the oxygen absorbent, the formation method of the multilayer structure, etc., the bonding property with the oxygen shielding layer, the heat sealing property of the oxygen permeable resin layer, and the oxygen The cushion layer and the oxygen-absorbing resin layer can be used to eliminate the oxygen-absorbing agent particles from protruding from the oxygen-absorbing resin layer, which may cause the oxygen-absorbing agent layer to protrude or be exposed from the surface of the permeable resin layer. It is deeply involved in extrusion laminating, and at that time, the oxygen permeable resin inner layer is also involved in the partial cushioning function, and it is not necessary to cool by close contact with the cooling roll, etc. As a result of repeated studies and experimental trials, a new extrusion lamination method, which is a basic element of the present invention, can be found and the present invention has been created.

Briefly speaking, the novel extrusion laminating method which is a basic element of the present invention is a method in which a cushioning resin layer is extrusion laminated to an oxygen-shielding outer layer fed from a supply roll or the like, and then a cushioning resin layer is formed. An oxygen-absorbing resin layer is further extruded and laminated between the oxygen-permeable resin layer (first method), or a cushioning resin layer and an oxygen-absorbing layer between the oxygen-shielding outer layer and the oxygen-permeable resin layer. Co-extrusion of the resin layer (second method), which consists of both methods, characterized by the requirement to extrude and integrate the oxygen-absorbing resin into the cushion layer after the cushion layer is extruded or simultaneously (co-extrusion) Is.
In basic recognition, in the first method, the cushioning resin layer is extrusion laminated, and then the oxygen absorbing resin layer is extrusion laminated to the cushioning resin layer. Even if the fine agent particles protrude from the outer surface of the oxygen-absorbing resin layer due to non-uniform blending or aggregation, or form protrusions or protrusions, the cushion layer in the softened state immediately after extrusion is Absorbing the protrusion, it can sufficiently prevent the bonding failure between the oxygen absorbing resin layer and the cushion layer or the oxygen shielding outer layer, and the oxygen permeable resin layer is laminated simultaneously with the extrusion lamination of the oxygen absorbing resin layer, Even if the oxygen scavenger fine particles protrude from the outer surface on the inner layer side of the oxygen-absorbing resin layer due to uneven mixing or aggregation of the oxygen-absorbing resin layer, the oxygen-absorbing resin layer is cooled and hard by the oxygen-permeable resin layer. Or the surface of the oxygen-permeable resin is slightly softened by the heat of the extruded oxygen-absorbing resin so that a portion of the oxygen-absorbing agent particles protrude from the surface is absorbed, and the oxygen-permeable resin layer Protrusion to the inner and outer surfaces of the opposite surface is not allowed.
Furthermore, in the second method, since the cushioning resin layer and the oxygen absorbing resin layer are coextruded and laminated between the oxygen shielding outer layer and the oxygen permeable resin layer, the cushioning resin layer and the oxygen absorbing resin layer are laminated. In the case of the first method, the layer interface is melt-integrated and extruded and laminated, and the microscopic irregularities and protrusions due to protrusion of the oxygen-absorbing agent fine particles to the outer surface of the oxygen-absorbing resin layer are sufficiently absorbed and contained. In the same manner as in the above, the oxygen absorbing resin in which microscopic irregularities and protrusions due to protrusion of oxygen absorber fine particles are pushed back into the oxygen absorbing resin layer by a cold and hard oxygen permeable resin layer or the surface of the oxygen permeable resin is extruded. It is slightly softened by the heat of the resin, and a part of the protrusion of the oxygen scavenger fine particles is absorbed and contained in the surface portion, and the protrusion to the outer surface of the inner layer opposite to the oxygen permeable resin layer is not allowed.

  In the process of reaching the present invention, two or three layers of the cushioning resin layer, the oxygen-absorbing resin layer, and the oxygen-permeable resin layer are coextruded by an inflation film forming method or a T-die film forming method, Although the method of dry lamination of the oxygen shielding layer was also examined, as seen in Comparative Examples-1 and 2 described later, the oxygen scavenger fine particles aggregate due to poor blending, resulting in microprojections. Numerous occurrences occurred on the surface of the inner and outer layers, and hue unevenness and extreme thinning caused by resin flow inhibition caused by the irregularities occurred, and a multilayer film that could be put to practical use was not obtained.

By the way, looking back at the prior art in the previous patent document, Patent Document 3 describes an extrusion lamination method that is superficially similar to the above-described two extrusion lamination methods of the present invention. An oxygen-absorbing resin layer is extruded and laminated on the cushion layer on the shielding layer side, and then an oxygen-permeable resin inner layer is laminated, or an oxygen-absorbing resin layer is laminated on the cushion layer, and then an oxygen-permeable resin inner layer is laminated. Many laminating methods are often described, such as adhering a cooling roll and then laminating an oxygen shielding outer layer.
However, even if all the methods are scrutinized, there is no method that is the same as or similar to the method of the present invention in which the oxygen-absorbing resin is extruded and integrated into the cushion layer after the cushion layer is extruded or simultaneously (co-extrusion). It is obvious that this prior art does not suggest the present invention because there is no description suggesting the characteristics of the present invention described in paragraph 0011, and there is no description indicating the operation and effect of the present invention described later. is there.

  In the above, the background of the creation of the present invention and the basic components and features of the present invention have been described in overview, so the whole of the present invention will be overviewed here. [1] and [2] are basic inventions, and [3] to [5] are inventions as embodiments. (The inventions [1] to [5] are collectively referred to as the present invention.)

[1] In a method for producing an oxygen-absorbing multilayer film comprising an oxygen-shielding outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer, A thermoplastic resin is extruded and laminated to form an oxygen-shielding outer layer and a cushion layer, and then an oxygen-absorbing thermoplastic resin is extruded between the cushion layer and the oxygen-permeable thermoplastic resin film. A method for producing an oxygen-absorbing multilayer film, characterized by laminating.
[2] A method for producing an oxygen-absorbing multilayer film comprising an oxygen-shielding outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer; Production of an oxygen-absorbing multilayer film characterized by coextruding a thermoplastic resin serving as a cushion layer and an oxygen-absorbing thermoplastic resin between an oxygen-permeable thermoplastic resin film and laminating them Method.
[3] The oxygen-shielding outer layer is composed of a thermoplastic resin layer and a metal foil layer, and the oxygen-absorbing thermoplastic resin layer is a thermoplastic resin containing an oxygen absorbent, and an oxygen-permeable thermoplastic resin layer. Is a heat-sealable thermoplastic resin, the method for producing an oxygen-absorbing multilayer film according to [1] or [2].
[4] An oxygen-absorbing lid member in a plastic molded container, which is formed from the multilayer film produced by the method for producing an oxygen-absorbing multilayer film in [1] or [2].
[5] A packaging bag formed from a multilayer film produced by the method for producing an oxygen-absorbing multilayer film according to [1] or [2].

In the oxygen-absorbing multilayer film of the present invention, the oxygen-absorbing agent fine particles in the oxygen-absorbing resin layer form a fine uneven surface on the layer surface, and are bonded to the oxygen shielding layer by the minute unevenness through the adjacent cushion layer or further through the cushion layer. The problem of deteriorating the heat sealability of the oxygen-permeable resin layer or the oxygen-absorbing resin particles protruding or exposed from the layer surface of the oxygen-permeable resin layer and contaminating the contents contained in the container can be simplified. By means, it is possible to sufficiently prevent all layers of the multilayer film.
In other words, according to the present invention, in the oxygen-absorbing multilayer film, each layer is smooth even if the oxygen-absorbing agent fine particles are blended in the oxygen-absorbing resin layer. The oxygen scavenger fine particles do not protrude from the inner layer surface of the oxygen permeable resin.
Therefore, there is no occurrence of unevenness (microprojections) on the inner and outer layer surfaces of the multilayer film, and hue unevenness does not occur.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
The present invention relates to an improvement of a production method by extrusion lamination of a multilayer film excellent in oxygen absorption and shielding properties. This multilayer film is used as a molding material for an oxygen-absorbing multilayer container, for example, a lid member of a plastic molding container or Used for packaging bags.

(1) Oxygen absorption As is commonly known, oxygen absorption and shielding are, for example, the contents of food and medicines stored and stored in containers that are spoiled or chemically altered by oxygen. Therefore, it should be called “oxygen resistance”.
Since the plastic has a small amount of gas permeability, oxygen in the air that permeates through the container wall from the outside of the container wall and oxygen in the air that is present when the contents are stored in the container are The contents of medicines are chemically altered, or the growth of microorganisms that cause spoilage in the container is promoted, which causes a problem in terms of storage stability of the contents. A resin having an oxygen shielding property is used for at least one layer thereof, and in order to remove oxygen in the container, the use of a deoxidizing agent causes the oxygen scavenger present in the container wall to remove the oxygen in the container. The oxygen is absorbed and the inside of the container is maintained in a highly oxygen-free state.

(2) Multilayer film a. Layer Structure The multilayer film of the present invention is not particularly limited, but basically comprises an oxygen-shielding outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer. Is done.
FIG. 1 illustrates the laminated structure of the multilayer film 10 as a cross-sectional view, and includes an oxygen-shielding outer layer 11, a thermoplastic resin cushion layer 12, an oxygen-absorbing thermoplastic resin layer 13, and an oxygen-permeable thermoplastic resin inner layer. 14 is shown.
In addition, the multilayer film of this invention is not limited to said layer structure, For example, another intermediate | middle layer can also be provided and another outermost layer etc. can also be provided in an outer layer.

  The thickness of each layer is not particularly limited as a normal multilayer film. As a specific example, generally, the thickness of the inner layer of the oxygen permeable resin is preferably 10 to 150 μm. If the thickness of the inner layer is excessively increased, oxygen in the container may not be sufficiently absorbed. The thickness of the oxygen-absorbing resin layer is preferably 10 to 50 μm. The thickness of the cushion layer is preferably 10 to 100 μm. The thickness of the oxygen shielding outer layer is preferably 10 to 200 μm.

B. Layer material The outer layer (also referred to as a base film) uses an oxygen shielding resin such as an ethylene-vinyl alcohol copolymer or a polyamide resin as a thermoplastic resin for the outer layer in order to prevent oxygen from entering from the outside. . Specific examples of the ethylene-vinyl alcohol copolymer include a saponified copolymer obtained by saponifying an ethylene-vinyl acetate copolymer so that the saponification degree is 96 mol% or more, particularly 99 mol% or more. Is used. A metal foil such as an aluminum foil or a metal vapor deposition film may be used as the outer layer, and a combination of a metal foil and a thermoplastic resin is also employed. In addition, there is no problem even if there is a layer forming an outer layer further than the above outer layer.
As the thermoplastic resin as the cushion layer, a resin having a high cushioning property, that is, a resin having high flexibility and impact resistance is preferable, and a polyolefin-based resin is mainly used like the oxygen permeable resin inner layer.
For the oxygen-absorbing resin layer, polyolefin resin is used because some oxygen permeability is required for oxygen absorption.
As the oxygen permeable resin inner layer, a certain degree of oxygen permeability is required for oxygen absorption of the oxygen absorbing layer, and therefore, an oxygen permeable resin such as polyethylene resin or polypropylene resin is used. Since the inner layer becomes a heat seal layer when the multilayer film is used as a molding material for the multilayer container, the inner layer needs to have excellent heat sealability. Polypropylene resin has oxygen permeability and heat sealability, and has excellent mechanical properties such as impact resistance and chemical properties such as chemical resistance, as well as excellent moldability and economy. It is suitable as an inner layer thermoplastic resin. Specific examples of the polypropylene resin include isotactic polypropylene, ethylene-propylene copolymer, propylene-butene-1 copolymer, and blends thereof. These polypropylene resins are used in the form of a composition containing a white pigment such as titanium oxide in order to conceal the black color of the iron-based oxygen scavenger and the like compounded in the oxygen-absorbing resin layer. Is done.
A preferred example of the layer structure of the multilayer film of the present invention is: outer layer (base film): PET 12 μm—aluminum foil 7 μm / cushion layer: polyolefin 15 μm / oxygen-absorbing resin layer 25 μm / inner layer: polyolefin 30 μm.

C. Oxygen absorber The oxygen absorber is preferably an iron-based oxygen absorber as a representative oxygen absorber (oxygen absorber) excellent in oxygen absorption and economy, and it has excellent reducibility (from surrounding substances). Deoxygenation) provides a strong oxygen absorption effect.
In addition, as an iron-type oxygen absorber, what was conventionally used for this kind of application can be used, for example, reducing iron, ferrous oxide, iron tetroxide, iron carbide, silicon iron, Examples thereof include iron carbonyl and iron hydroxide. These can be used singly or in combination of two or more. The normal particle size and density are also suitable. If the one having an excessively large average particle diameter is used, a large number of irregularities are generated, and fish eyes and the like are generated when forming into a multilayer sheet, which may impair the appearance of the container. If the average particle size is too small, it is expensive and difficult to handle.
In general, the iron-based oxygen scavenger is preferably 1 to 200% by weight, particularly 10 to 100% by weight per resin. If the amount of the iron-based oxygen scavenger is lower than the above range, it becomes difficult to suppress the oxygen concentration in the container to a concentration suitable for the growth of microorganisms, or even if used in a larger amount than the above range, Not only is there no particular effect in terms of oxygen concentration reduction, but there is a tendency to be disadvantageous in terms of moldability and price.
An oxygen accelerator may be used in combination with the oxygen absorber, and an oxygen accelerator such as an iron-based oxygen absorber is promoted by using an oxidation accelerator (catalyst) such as an alkali compound or an alkaline earth compound in combination. These promote the oxygen scavenging effect of the oxygen scavenger through absorption of moisture.

(2) Production of multilayer film in the present invention a. Basic features The present invention relates to the joining of the oxygen-absorbing resin layer and the adjacent cushion layer or oxygen-shielding layer due to the oxygen-absorbing agent particles in the multilayer film protruding from the oxygen-absorbing resin layer. In order to sufficiently prevent the deterioration of heat sealability and heat sealability of the oxygen permeable resin layer, and the protrusion and exposure of oxygen absorber fine particles from the layer surface of the oxygen permeable resin layer, A specific extrusion lamination method is adopted.
In particular, it has a feature in the extrusion lamination method of a cushion layer and an oxygen-absorbing resin layer, and does not require cooling by close contact of a cooling roll as in the prior art.

A novel extrusion laminating method, which is a basic element of the present invention, is a method in which a cushioning resin layer is extrusion laminated to an oxygen shielding outer layer film fed from a supply roll, and then fed from the cushioning resin layer and the supply roll. An oxygen-absorbing resin layer is further extruded and laminated between the oxygen-permeable resin layer film (first method), or an oxygen-shielding outer layer film and an oxygen-permeable resin layer that are both fed from a supply roll A cushioning resin layer and an oxygen-absorbing resin layer are coextruded between the film and laminated (second method).
The extrusion laminating method is performed by melt-extruding to a predetermined width and thickness through a single layer such as a T-die or a multilayer multiple die after melt-kneading with an extruder corresponding to each resin layer.
The film of each layer to be fed is manufactured in advance by a normal film forming method such as extrusion molding or dry lamination.

B. Action in extrusion lamination In the first method, the cushioning resin layer is extrusion laminated, and then the oxygen absorbing resin layer is extrusion laminated to the cushioning resin layer. Due to uneven blending or aggregation, the cushion layer in the softened state immediately after extrusion absorbs minute irregularities and protrusions even if it protrudes from the outer surface of the oxygen-absorbing resin layer to form minute irregularities or protrudes. Encapsulated, it can sufficiently prevent poor bonding between the oxygen absorbing resin layer and the cushion layer or oxygen shielding outer layer, and the oxygen permeable resin layer is laminated simultaneously with the extrusion lamination of the oxygen absorbing resin layer. Even if the fine particles protrude from the outer surface on the inner layer side of the oxygen-absorbing resin layer, the oxygen-permeable resin layer solidified at a relatively low temperature pushes it back into the oxygen-absorbing resin layer, or the oxygen-permeable resin layer. The surface of the transient resin is slightly softened by the heat of the extruded oxygen-absorbing resin, so that the surface portion absorbs and includes a part of the protrusion of the oxygen-absorbing agent fine particles, and on the outer surface of the inner layer opposite to the oxygen-permeable resin layer. Don't stick out.

  In the second method, since the cushioning resin layer and the oxygen-absorbing resin layer are coextruded and laminated between the oxygen-shielding outer layer and the oxygen-permeable resin layer, the layer interface between the cushioning resin layer and the oxygen-absorbing resin layer is laminated. Is melt-integrated and extruded and laminated, and the microscopic irregularities and protrusions due to protrusion of the oxygen-absorbing agent fine particles to the outer surface of the oxygen-absorbing resin layer are sufficiently absorbed and encapsulated, and as in the case of the first method The microscopic irregularities and protrusions caused by the protrusion of the oxygen absorber fine particles are pushed back into the oxygen-absorbing resin layer by the solidified oxygen-permeable resin layer, or the heat of the oxygen-absorbing resin in which the surface of the oxygen-permeable resin is extruded. Thus, the surface is softened slightly so that a part of the protrusion of the oxygen-absorbing agent fine particles is absorbed and contained and does not protrude to the outer surface of the inner layer opposite to the oxygen-permeable resin layer.

C. First Extrusion Laminating Method The first extrusion laminating method comprises an oxygen-absorbing multilayer film comprising an oxygen-shielding outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer. In this manufacturing method, an oxygen-shielding film is extruded and laminated with a thermoplastic resin to form an oxygen-shielding outer layer and a cushion layer, and then oxygen is absorbed between the cushion layer and the oxygen-permeable thermoplastic resin film. This is a method for producing an oxygen-absorbing multilayer film characterized by extruding a heat-resistant thermoplastic resin and laminating them.
The first extrusion lamination method is shown as a schematic diagram in FIG. 2, and an oxygen shielding film 22 fed from a supply roll is transferred from a die head 21 of an extruder to a thermoplastic resin 23 serving as a cushion layer. The oxygen shielding outer layer and the cushion layer are integrally formed by the nip roll 24, and the extrusion layer is then inserted between the cushion layer and the oxygen permeable thermoplastic resin film 27 fed from the supply roll. Oxygen-absorbing thermoplastic resins 26 are extruded from the die head 25 of the molding machine, and are laminated by nip rolls 28.

D. Second extrusion lamination method The second extrusion lamination method comprises an oxygen-absorbing multilayer film comprising an oxygen-shielding outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer. In this manufacturing method, a thermoplastic resin that becomes a cushion layer and an oxygen-absorbing thermoplastic resin are coextruded between an oxygen-shielding film and an oxygen-permeable thermoplastic resin film, and then laminated. Is a method for producing an oxygen-absorbing multilayer film.
The second extrusion laminating method is shown schematically in FIG. 3, and an extruder is provided between an oxygen shielding film 32 and an oxygen permeable thermoplastic resin film 35 fed from a supply roll. The thermoplastic resin 33 and the oxygen-absorbing thermoplastic resin 34 serving as a cushion layer are co-extruded from the die head 31 and laminated by a nip roll 36.

(3) Use of multilayer film The multilayer film produced according to the present invention is excellent in oxygen shielding properties and oxygen absorption properties, and is capable of bonding between layers and oxygen-permeable resin due to oxygen scavenger fine particles in the oxygen-absorbing resin layer. Since there is no deterioration of the heat sealability of the layer and no oxygen absorber fine particles protrude from the layer surface of the oxygen permeable resin layer, it is very useful as a molding material for a multilayer container.
In particular, it is suitably used for oxygen-absorbing lid members and packaging bags in plastic molded containers for food storage or non-food storage such as pharmaceuticals and cosmetics.

Hereinafter, the present invention will be described in detail by way of examples. However, the present invention is intended to explain the present invention more specifically, and it is obvious that the present invention is not limited to the following examples. is there.
Example-1
This example implements the first extrusion lamination method described in paragraph 0027, and a specific example thereof is shown in FIG.
[Material composition]
Outer layer (base film): PET 12 μm-aluminum foil 7 μm / cushion layer: polyolefin 15 μm / oxygen-absorbing resin layer 25 μm / inner layer: polyolefin 30 μm As the oxygen absorbent, 30% by weight of reduced iron was blended in the oxygen-absorbing resin layer.
[Production method]
A thermoplastic resin 23 serving as a cushion layer is extruded and laminated from the die head 21 of the extruder to the oxygen-shielding film 22 to be fed, and an oxygen-shielding outer layer and a cushion layer are formed by a nip roll 24, Next, an oxygen-absorbing thermoplastic resin 26 was extruded from a die head 25 of an extruder and laminated with a nip roll 28 between the cushion layer and the oxygen-permeable thermoplastic resin film 27 to be fed.
[Evaluation methods]
Using 700 width × 200 m, the state of occurrence of surface irregularities (microprojections) on the surface of the inner and outer layers was inspected with a Hutech inspection machine.
In addition, the hue unevenness derived from the die line and the irregularity was visually inspected.

Example-2
This example implements the second extrusion lamination method described in paragraph 0028, and a specific example thereof is shown in FIG.
[Production method]
Between the oxygen-shielding film 32 and the oxygen-permeable thermoplastic resin film 35 to be fed, from the die head 31 of the extruder, a thermoplastic resin 33 serving as a cushion layer and an oxygen-absorbing thermoplastic resin 34 are provided. Were coextruded and laminated by a nip roll 36.
The material configuration and the evaluation method were the same as in Example-1.

[Comparative Example-1]
A three-layer coextruded film of a cushion layer, an oxygen-absorbing resin layer, and an oxygen-permeable resin layer was formed by an inflation film forming method, and an oxygen shielding layer was laminated by dry lamination.
The material configuration and the evaluation method were the same as in Example-1.

[Comparative Example-2]
A three-layer coextruded film of a cushion layer, an oxygen-absorbing resin layer, and an oxygen-permeable resin layer was formed by a T-die film forming method, and an oxygen shielding layer was laminated by dry lamination.
The material configuration and the evaluation method were the same as in Example-1.
The evaluation results of each example and each comparative example are summarized in Table 1.

[Consideration of results of Examples and Comparative Examples]
By contrasting each of the above examples and comparative examples, according to the production method of the present invention, in the multilayer film, there is almost no occurrence of unevenness, no hue unevenness, and an excellent oxygen-absorbing multilayer film material. It has been made clear.

It is sectional drawing which shows the laminated structure of the multilayer film of this invention. It is the schematic which shows the 1st extrusion lamination method of this invention. It is the schematic which shows the 2nd extrusion lamination method of this invention.

Explanation of symbols

10: Multilayer film 11: Oxygen-shielding outer layer 12: Thermoplastic resin cushion layer 13: Oxygen-absorbing thermoplastic resin layer 14: Oxygen-permeable thermoplastic resin inner layer

21: Extruder die head 22: Oxygen shielding film 23: Thermoplastic resin cushion layer 24: Nip roll 25: Extruder die head 26: Oxygen absorbing thermoplastic resin 27: Oxygen permeable thermoplastic resin film 28: Nip roll

31: Die head of extrusion molding machine 32: Oxygen shielding film 33: Thermoplastic resin cushion layer 34: Oxygen absorbing thermoplastic resin 35: Oxygen permeable thermoplastic resin film 36: Nip roll

Claims (5)

In a method for producing an oxygen-absorbing multilayer film comprising an oxygen-shielding outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer, the oxygen-shielding film is a thermoplastic resin. Forming an oxygen-shielding outer layer and a cushion layer, and then extruding an oxygen-absorbing thermoplastic resin between the cushion layer and the oxygen-permeable thermoplastic resin film and laminating them A method for producing an oxygen-absorbing multilayer film characterized by the following. In a method for producing an oxygen-absorbing multilayer film comprising an oxygen-shielding outer layer, a thermoplastic resin cushion layer, an oxygen-absorbing thermoplastic resin layer, and an oxygen-permeable thermoplastic resin inner layer, the oxygen-shielding film and the oxygen-permeable film A method for producing an oxygen-absorbing multilayer film, comprising: coextruding a thermoplastic resin serving as a cushion layer and an oxygen-absorbing thermoplastic resin between the two thermoplastic resin films and laminating them. The oxygen-shielding outer layer consists of a thermoplastic resin layer and a metal foil layer, the oxygen-absorbing thermoplastic resin layer is a thermoplastic resin containing an oxygen absorbent, and the oxygen-permeable thermoplastic resin layer is heat-sealed. A method for producing an oxygen-absorbing multilayer film according to claim 1 or 2, wherein the thermoplastic resin is a heat-resistant thermoplastic resin. An oxygen-absorbing lid member in a plastic molded container, which is formed from the multilayer film produced by the method for producing an oxygen-absorbing multilayer film according to claim 1 or 2. A packaging bag formed from a multilayer film produced by the method for producing an oxygen-absorbing multilayer film according to claim 1 or 2.

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