JP2005088200A - Styrenic resin laminated foamed sheet and molded container comprising the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a styrenic resin laminated foamed sheet capable of obtaining a lightweight molded container excellent in strength and curved surface printability. <P>SOLUTION: This styrenic resin laminated foamed sheet is constituted by laminating a styrenic resin non-foamed film with a basis weight of 70-130 g/m<SP>2</SP>on a styrenic resin foamed sheet characterized in that a basis weight is 190-230 g/m<SP>2</SP>, the residual amount of a foaming agent is 0.45-0.55 mol/kg and the density of a part up to a thickness of 150 μm from the surface on which the film is not laminated of the foamed sheet is 0.25-0.35 g/cm<SP>3</SP>. The bending maximum load when deformation is applied to the laminated foamed sheet from the film surface side according to JIS-K7221 is 3.5-6.0 N, the thickness thereof is 1.8-2.3 mm and the basis weight thereof is 280-360 g/m<SP>2</SP>. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a lightweight and strong styrene-based resin laminated foam sheet used for instant ramen containers and the like.

  For containers such as instant ramen containers, a styrene resin laminated foam sheet in which a styrene resin non-foamed film layer is laminated on the surface of a styrene resin foam sheet is light, has high heat insulation, and has a high strength and is difficult to break. Therefore, it is used in large quantities. However, the price of these foods is low, and hence the reduction of the container price is an issue, and the weight reduction of the foamed sheet layer and the thinning of the film layer have been required. In addition, this requirement has been further strengthened by the recent enforcement of the Container Recycling Law.

  However, simply reducing the weight of the foam sheet layer naturally reduces the strength of the molded container, which causes problems such as breakage and breakage of the container in the molding process, wrinkles, and loss of appearance. Moreover, it is widely practiced to form the styrene resin laminated foam sheet so that the film surface is on the outside of the container, and then apply curved printing to the outer surface of the container to give the container design, but the film is too thin. Since the smoothness of the surface of the obtained container is impaired, printing skipping or the like occurs, and the appearance of the container is greatly impaired.

In order to meet the demand for weight reduction in the market while avoiding these problems, a method for increasing the strength of the foam sheet surface has been proposed (see, for example, Patent Document 1). However, this method is effective when the foam sheet itself is molded into a shallow shape such as a tray, but when the laminated foam sheet is molded into a deep shape container such as a ridge, the moldability is greatly reduced. And the problem that the adhesiveness of a foam sheet falls arises. Furthermore, it is also proposed to laminate films on both sides (for example, Patent Document 2). However, this method has a problem in that the manufacturing cost increases and productivity deteriorates in exchange for the improvement in strength. In addition to these methods, there has been proposed an increase in strength by adjusting the amount of residual foaming agent and the density of the surface layer within a specific range for the purpose of container molding (for example, Patent Document 3). However, the present invention is intended to improve the top and bottom compression strength, and does not suggest a method for satisfying all requirements required for a molded container such as lip compression strength and piercing strength. For this reason, the limit of the basis weight of the styrene resin laminated foam sheet is about 380 to 420 g / m ^2, which is not sufficient to meet the market demand for a lighter container.
JP-A-10-330523 JP 54-133971 A JP 2001-310405 A

  An object of the present invention is to provide a styrene-based resin laminated foam sheet having excellent moldability and a molded container that can be molded into a container that is lightweight and has excellent strength and curved surface printing.

  As a result of diligent research regarding the improvement of the strength of the container formed from the styrene-based resin laminated foam sheet, such as the vertical compression strength, the lip compression strength, and the piercing strength, It was found that the strength, particularly the lip compression strength, can be improved. In addition, the bending strength of the laminated foam sheet is determined by the basis weight of the foam sheet and non-foamed film constituting it, the density of the surface layer portion of the foam sheet (particularly, the surface on which the film is not laminated), and the amount of residual foaming agent. And found the present invention.

That is, the present invention
The basis weight is 190 to 230 g / m ² , the residual foaming agent amount is 0.45 to 0.55 mol / kg, and the density of the portion having a thickness of 150 μm from the surface on which the film is not laminated is 0.25 to 0.35 g / cm ^3. Is a laminated foam sheet in which a non-foamed styrene resin film having a basis weight of 70 to 130 g / m ² is laminated on the styrene foam sheet, and is deformed from the film surface side of the laminated foam sheet by a method according to JIS-K7221. The styrene-based resin laminated foam sheet having a thickness of 1.8 to 2.3 mm and a basis weight of 280 to 360 g / m ² having a bending maximum load of 3.5 N or more when applied (Claim 1),
The styrene resin laminated foam sheet according to claim 1, wherein the density of the portion having a thickness of 150 μm from the surface of the surface on which the film of the styrene resin foam sheet is laminated is 0.35 to 0.45 g / cm ³ .
The styrene-based resin laminated foam sheet according to claim 1 or 2, wherein a silicone oil having an application amount of 0.03 to 0.10 g / m ² is applied to at least one surface (Claim 3).
And the container obtained by shape | molding the styrene resin laminated foam sheet in any one of Claims 1-3 (Claim 4).
About.

  By molding the styrene-based resin foam laminated sheet according to the present invention, a container having a light weight, high strength and excellent curved surface printing is obtained.

  The physical properties of containers made of styrene resin laminated foam sheets are required to have top and bottom compression strength, lip compression strength, and piercing strength. Of these, top and bottom compression strength and lip compression strength must have high strength against bending deformation. It is. Therefore, in order to obtain a container with high strength, the maximum bending load measured by a method according to JIS-K7221 needs to be 3.5 N or more. Specifically, a sample cut to a length of 150 mm × width 25 mm is placed on a support base having a radius of 5 mm at the tip portion so that the film surface is on top, and a pressure wedge with a tip radius of 5 mm is 10 mm / min. Measurement is performed with deformation. This measurement is performed for each of the five points in the width direction and the longitudinal direction of the laminated foam sheet, and the average of the maximum bending load is obtained.

  When this maximum bending load is less than 3.5 N, a container having sufficient top and bottom compression strength and lip compression strength cannot be obtained. Further, the higher the maximum bending load, the better the container strength, but 6.0 N was the limit in the laminated foam sheet of the present invention. Even if a sheet having a bending strength higher than this is obtained, the strength is increased, but on the other hand, it is fragile and easily broken, which is not suitable for practical use.

  The styrene resin foam sheet is a polystyrene homopolymer resin, a vinyl monomer such as (meth) acrylic acid, maleic anhydride, acrylonitrile, acrylic (meth) acrylate and the like, and a diene monomer such as butadiene and isoprene. And polystyrene resins made of a mixed resin of these resins and polyphenylene oxide, nucleating agents such as talc, and, if necessary, plasticizers such as liquid paraffin It is obtained by mixing and melting a lubricant such as ethylenebisstearylamide, magnesium stearate, fatty acid ester, etc. in an extruder, press-fitting a blowing agent such as butane, cooling to an appropriate foaming temperature, and then extruding and foaming from a circular die. .

In order to obtain a laminated foam sheet having a basis weight of 280 to 360 g / m ² excellent in strength in the present invention, the basis weight of the foam sheet needs to be 190 to 230 g / m ² . If the basis weight is less than 190 g / m ² , the bending strength of the laminated foamed sheet will be insufficient no matter how thick the non-foamed film is. Further, when it is attempted to secure the thickness of the laminated sheet necessary for molding with a low basis weight, the density of the foamed sheet becomes low, so that it tends to break and becomes unsuitable for forming into a deep drawing shape such as a wrinkle. Further, when the basis weight exceeds 230 g / m ² , the film must be thinned, resulting in problems such as reduced puncture strength and impaired curved surface printing.

  When producing a foam sheet by extrusion foaming, the density of the foam sheet surface can be increased by blowing air to the foam sheet surface and quenching. In order to obtain a target surface density, the temperature of the cooling air, the air volume, the air speed, and the spraying position may be appropriately adjusted in accordance with the sheet surface temperature immediately after extrusion, the extrusion resin discharge amount, the sheet take-up speed, and the like. The density of the surface layer portion of the foamed sheet is determined by cutting out the surface layer portion (portion 150 μm from the surface) with an accuracy within ± 15 μm and measuring the weight.

Here, about the surface which does not laminate | stack a film, it is necessary for the density of the part of thickness 150 micrometers from the surface to be 0.25-0.35 g / cm < ³ >. This forms a rigid layer on the surface, and the bending strength of the laminated foamed sheet can be improved by the reinforcing effect of this layer. If the density of the surface layer of 150 μm is less than 0.25 g / cm ³ , the reinforcing effect is insufficient, and the strength, particularly the lip compression strength is lowered. On the other hand, if it exceeds 0.35 g / cm ³ , the elongation of the surface of the foamed sheet is extremely lowered, and molding defects such as cracks and cracks occur.

Moreover, it is preferable that the density of the part of 150 micrometers from the surface of the surface which laminates | stacks a film is 0.35-0.45 g / cm < ³ >. If the density is 0.35 g / cm ³ or more, fine bubbles having a diameter of about 50 μm are generated on the surface of the foam sheet on which the film is laminated by heating during molding. Thereby, the surface smoothness of a container film lamination surface improves, and a container with favorable curved-surface printing suitability can be obtained. Moreover, the puncture strength of the container is also improved. On the other hand, if the density exceeds 0.45 g / cm ³ , the fine bubbles described above are generated by the heat applied during film lamination. When the fine bubbles are generated in the laminated foam sheet stage, the fine bubbles are expanded by the heating at the time of molding, and are further formed into a continuous bubble. Thereby, irregularities are generated on the surface of the container, and the appearance and surface smoothness of the container are greatly impaired.

  The amount of foaming agent remaining in the foamed sheet is mainly determined by the amount of foaming agent that is pressed during extrusion and the resin temperature during extrusion. Further, increasing the density of the surface layer portion described above also has an effect of suppressing dissipation of the foaming agent from the surface of the foamed sheet, and is effective in securing the amount of residual foaming agent.

  As the amount of the foaming agent gas remaining in the foamed sheet increases, the gas pressure in the bubbles of the foamed sheet increases, and the bending strength of the foamed sheet improves. In order to obtain a sufficiently high strength container, the amount of the remaining foaming agent needs to be 0.45 to 0.55 mol / kg. If the amount of residual foaming agent is less than 0.45 mol / kg, the top and bottom compression strength and the lip strength are lowered. In addition, when the amount of residual foaming agent exceeds 0.55 mol / kg, the foaming agent gas is dissipated from the foamed sheet at the time of lamination, resulting in a gap at the lamination interface, and the interface between the film and the foamed sheet is peeled off during heating of molding. In other words, the so-called delamination phenomenon occurs, and the appearance of the container is greatly impaired. Moreover, it becomes a cause of generation | occurrence | production of the microbubble by the heating at the time of the above-mentioned lamination | stacking.

  In order to suppress the dissipation of the foaming agent in the laminated foam sheet and maintain the strength properties for a long time, the closed cell ratio of the foam sheet is preferably 85% or more, and more preferably 90% or more. The closed cell ratio of the foam sheet can be measured with an Air Comparison Pycnometer such as Model 930 manufactured by BECKMAN. When the closed cell ratio is less than 85%, the remaining foaming agent in the foamed sheet is quickly dissipated, it is difficult to maintain the pressure in the air bubbles, and the secondary foaming force due to strength and heating during molding may be reduced.

  For the non-foamed styrene resin film laminated on the surface of the foamed sheet, the styrenic resin used in the above-mentioned styrenic resin foamed sheet can be used. A styrene-based resin film containing a rubber component made of a copolymer resin with a series monomer, particularly a film made of a high-impact polystyrene resin as a raw material is preferable from the viewpoint of adhesion to a foam sheet and impact resistance of the film.

  For the lamination of the film on the surface of the foamed sheet, a method of extruding and laminating a film resin on the surface of the foamed sheet using a T die is applied. Only one layer of extruded film may be laminated, or a thermoplastic resin non-foamed film may be laminated on the outer surface through the extruded film. At this time, if the film resin temperature is too low, it becomes impossible to secure the adhesive force with the foam sheet, and if it is too high, fine bubbles are generated on the surface of the foam sheet that adheres to the film due to the heat of the film, This may cause adhesion failure and burns during molding, and the thermoplastic resin non-foamed film laminated on the outer surface will expand and contract to cause wrinkles. For this reason, it is necessary to select suitably the temperature of the film resin extruded from a T-die according to the fluidity of the resin used. For example, in the case of a high impact polystyrene resin, the temperature is preferably 210 to 240 ° C.

In the case of laminating the extruded film only one layer, the basis weight of the non-foamed film is required to be 70~130g / m ^2. If it is less than 70 g / m ² , the puncture strength is insufficient, and the curved surface printing suitability is impaired. On the other hand, if it exceeds 130 g / m ² , the basis weight of the foamed sheet will be lowered as the film becomes heavier, leading to a decrease in the bending strength of the laminated foamed sheet.

For the non-foamed thermoplastic resin film laminated on the outer surface via an extruded film, use any material other than styrene resins, as long as it is applicable to food packaging applications such as polyolefin resins such as polyethylene and polypropylene, and PET. Is possible. In addition, it is possible to impart designability to the molded container by laminating the pre-printed film. Moreover, since these films manufactured by the T-die method, the inflation method, and the like are stretched to some extent in the manufacturing process, it is also expected to improve the lip compression strength by laminating them. The basis weight of the thermoplastic resin non-foamed film laminated via the extruded film is a 20 to 40 g / m ^2, it is preferable that the basis weight of the entire film layer and 70~130g / m ^2. If the basis weight of the thermoplastic resin non-foamed film is less than 20 g / m ² , wrinkles are likely to occur in the film during lamination, and stable production becomes difficult. On the other hand, if it exceeds 40 g / m ² , the cost of the film itself becomes high, which is meaningless from the viewpoint of cost effectiveness.

Conventionally, silicone oil is applied before or after molding in consideration of blocking during container stacking after container molding (contains containers that do not separate while overlapping) and slipping in the content filling line. By applying silicone in advance, the slipping property when the mold and the sheet come into contact with each other is improved, and it is possible to make the circumference of the container (the density balance between the bottom and the mouth) uniform. In particular, in the case of a laminated foam sheet that has been reduced in weight, the lip compression strength is impaired because it is easier to stretch than the conventional heavy weight sheet and the container mouth becomes lighter. For this reason, it is preferable to make the circumference of the meat uniform by applying silicone oil. The surface on which the silicone is applied may be either a film laminated surface or a film non-laminated surface, or may be applied to both surfaces. The application of silicone oil may be performed in a lamination process or may be performed immediately before molding in a molding process. As a coating method, a general method such as a cloud chamber method, a spray method, or a roll coater method can be used. The application amount of silicone oil is preferably 0.03 to 0.10 g / m ² . If the coating amount is less than 0.03 g / m ² , the effect of improving the slipping property may not be recognized. Even if the amount exceeding 0.10 g / m ² is applied, no further effect is exhibited, and the film is not laminated. When it is applied to the surface, the heat resistance of the foam sheet surface may be reduced (discoloration), and when it is applied to the film laminated surface, printing failure may occur during curved surface printing.

  The laminated foam sheet obtained in this way can be formed into a container by a widely used method. In other words, after heating with an infrared heater or the like to secondarily foam the laminated foamed sheet, the container is shaped by fitting with a mold and then punched out from the sheet. The appropriate secondary foam thickness of the sheet is determined by the mold design at this time. In general, when forming into a bowl shape, a secondary thickness of about 4.5 to 5.5 mm is required, and it is necessary to determine the primary thickness of the foam sheet in accordance with this. In order to sufficiently draw out the strength of the laminated foamed sheet, the secondary thickness is about 80 to 90% of the maximum secondary thickness of the laminated foamed sheet (secondary foamed thickness immediately before heating and burning of the sheet). It is desirable to perform heating and molding, and therefore, the thickness of the laminated foam sheet needs to be 1.8 to 2.3 mm. If the thickness is less than 1.8 mm, it is necessary to increase the heating at the time of molding, which leads to a decrease in container strength and poor appearance due to excessive heating. On the other hand, when the thickness exceeds 2.3 mm, sufficient heating cannot be performed at the time of molding, and the expansion of the laminated foamed sheet is insufficient due to insufficient heating, resulting in molding defects such as cracking.

  Hereinafter, specific examples will be described.

(Examples 1-4)
Using a polystyrene resin prepared by suspension polymerization, an extruded foam sheet having a width of 1050 mm having the specifications shown in Table 1 was prepared using butane gas containing 85% isobutane as a foaming agent. In addition, all the closed cell ratios of the obtained foam sheet were 90% or more.

  The amount of foaming agent remaining in these foamed sheets was measured using a PEG20M column and a DNP column in a gas chromatograph manufactured by Shimadzu after putting the foamed sheet into a sealed container and reducing the pressure and heating to collect the gas components remaining inside. Calculated from the results. The basis weight was determined by cutting a 10 cm square sample at 10 points in the width direction and measuring the weight.

Table 1 shows a film using A & M high impact polystyrene resin 475D by extrusion lamination to the obtained foamed sheet. It laminated | stacked so that it might become the fabric weight shown to. As a result of measuring the surface temperature of the extruded film using a non-contact type surface thermometer in the lamination, it was 225 ± 3 ° C. in the width direction. In Example 4, a HIPS film SPH30 (30 μm = 32 g / m ² ) manufactured by Oishi Sangyo Co., Ltd. was laminated through a 90 g / m ² extruded film to obtain a three-layer laminated foam sheet. Furthermore, after the lamination, in the same lamination step, a silicone oil TSM 6344 made of Shin-Etsu silicone was applied to the surface on the film lamination surface side using a gravure coater.

The obtained laminated foam sheet is supplied to the FLC3 continuous molding machine manufactured by Asano Laboratories, and the film of the laminated foam sheet is placed in a container similar to Nissin Foods “Donbei” (caliber 144 mm × depth 75 mm, 36 pcs / shot). It shape | molded so that a lamination surface might become an outer side. The heating conditions were adjusted so that the secondary thickness during molding was 4.8 to 5.0 mm. The top and bottom compression strength, lip compression strength, and puncture strength of the obtained container were measured by the following methods. The measurement was performed on 36 shots, and the average value is shown in Table 1.
Top and bottom compression strength: Yield strength when the container is sandwiched between two plates with the mouth down and compressed from the bottom at a speed of 100 mm / min. Lip compression strength: Supports both ends in the container mouth TD direction, Load puncture strength when the end of the tube is compressed 80 mm at a speed of 100 mm / min: the maximum load when a needle with a diameter of 1.5 mm is pierced from the inner surface of the bottom of the container at 100 m / min and penetrated. Was evaluated whether it was possible to mold with good appearance without causing naki (a phenomenon in which the foamed sheet was stretched locally) and delami (a phenomenon in which the foamed sheet and the film were peeled off during molding and heating) during container molding. As for printability, curved surface printing was performed two days after the container was formed, and it was visually evaluated whether there was any ink smearing or jumping.

  The results obtained are summarized in Table 1.

比較例１は従来使用されてきた丼成形用の積層発泡シートである。目付は４００ｇ／ｍ²を越え、成形性、印刷性も申し分なく、一般に要求される丼容器の強度物性である天地圧縮強度１００Ｎ以上、リップ圧縮強度１０Ｎ以上、突き刺し強度１０Ｎ以上を満たしている。一方、本発明による実施例１〜４は目付が軽いにも関わらず、高い最大曲げ荷重を有し、容器の強度物性は比較例１と同等であり、成形性、印刷性にも問題がなく、バランスのとれた品質を有していることがわかる。

Comparative Example 1 is a conventionally used laminated foam sheet for forming cocoons. The basis weight exceeds 400 g / m ² , and the moldability and printability are satisfactory, and the generally required strength physical properties of the dredged container are 100 N or more, lip compression strength of 10 N or more, and piercing strength of 10 N or more. On the other hand, Examples 1 to 4 according to the present invention have a high maximum bending load although the basis weight is light, and the strength properties of the container are equivalent to those of Comparative Example 1, and there is no problem in moldability and printability. It can be seen that it has a balanced quality.

  Comparative Example 2 is a thinner film than Comparative Example 1. In Comparative Example 3, a thick film was laminated on a high strength foamed sheet grade for forming a tray container. Neither was balanced in quality, and the containers lacked strength.

  In Comparative Examples 4 to 5, the foam sheet and the basis weight of the film are the same as those in the example. In Comparative Example 4, the density of the non-laminated surface was too low, the maximum bending load of the laminated foam sheet was low, and the lip compression strength was particularly insufficient in the container. In Comparative Example 5, the density of the non-lamellar surface was too high and the maximum bending load was high, but cracks occurred during molding, which was insufficient as the strength of the container. Moreover, since the residual volatile matter was too high, a delamination phenomenon in which the foamed sheet and the film peeled during molding occurred, and printability was also impaired.

Comparative Examples 6 and 7 are the same laminated foam sheets as Comparative Example 4, but in Comparative Example 6 where the silicone oil application was not performed, the circumference of the meat was concentrated on the bottom and the compression strength and piercing strength were improved, but the mouth was As it was stretched, cracks occurred and the lip compression strength was greatly impaired. In Comparative Example 7 in which the amount of silicone oil applied was too large, printing failure occurred due to ink repelling during printing, and the appearance was very poor.

Claims (4)

The basis weight is 190 to 230 g / m ² , the residual foaming agent amount is 0.45 to 0.55 mol / kg, and the density of the portion having a thickness of 150 μm from the surface on which the film is not laminated is 0.25 to 0.35 g / cm ^3. Is a laminated foam sheet in which a non-foamed styrene resin film having a basis weight of 70 to 130 g / m ² is laminated on the styrene foam sheet, and is deformed from the film surface side of the laminated foam sheet by a method according to JIS-K7221. A styrene-based resin laminated foam sheet having a thickness of 1.8 to 2.3 mm and a basis weight of 280 to 360 g / m ² , wherein the bending maximum load when applied is 3.5 N or more and 6.0 N or less. The styrene resin laminated foam sheet according to claim 1, wherein the density of the portion having a thickness of 150 µm from the surface of the surface on which the film of the styrene resin foam sheet is laminated is 0.35 to 0.45 g / cm ³ . The styrene-based resin laminated foam sheet according to claim 1 or 2, wherein a silicone oil having an application amount of 0.03 to 0.10 g / m ² is applied to at least one surface.   The container obtained by shape | molding the styrene resin laminated foam sheet in any one of Claims 1-3.