JP2022035355A - Evaluation method and manufacturing method of sheet for foamed heat-insulation paper container - Google Patents

Abstract

To provide a sheet for a foamed heat-insulation paper container, which can be foamed evenly even when lamination is performed at a high speed, and a method for evaluating a heat insulation property of the sheet for the foamed heat-insulation paper container without going through a foaming process.SOLUTION: There is provided an evaluation method of a sheet for a foamed heat-insulation paper container, which measures a tensile strength of a polyethylene resin in a flow direction, thereby evaluation of a heat insulation property of the sheet for the foamed heat-insulation paper container and provision of the sheet for the foamed heat-insulation paper container having stable foaming property are realized without going through a foaming process.SELECTED DRAWING: Figure 1

Description

The present invention relates to a method for manufacturing a sheet for an effervescent heat insulating paper container.

Insulated containers are generally used in containers for instant noodles in cups and containers for hot food and drink such as coffee and soup.
Conventionally, as a heat insulating container used for this purpose, a container made of expanded polystyrene has been known, but there is a problem that the container is bulky and dust increases because the entire container is foamed. In addition, the strength is lower than that of a paper container, and there is a problem that it is easily damaged when transported with hard contents (noodle lumps, etc.) in it.

In order to solve this problem, a polyethylene resin with a low melting point is laminated on the outer wall surface of the paper container and heated to foam the polyethylene resin using the vapor pressure of the moisture contained in the paper as the base material. Discloses a technique for manufacturing a foamed heat insulating paper container (Patent Documents 1 to 3). However, there is a problem that it is difficult to control the foam layer (heat insulating layer).

As a method for controlling the foam layer, a method for controlling the composition of the polyethylene resin, the water content and the weighing of the paper base material (Patent Document 4), and the Oken-style smoothness and transparency of the surface on which the polyethylene layer of the paper base material is laminated are used. A method of controlling the air resistance (Patent Document 5), a method of controlling the molecular weight distribution of the polyethylene resin, the melt flow rate and the melt tension (Patent Document 6) are known.

Japanese Unexamined Patent Publication No. 57-110439 Japanese Unexamined Patent Publication No. 05-0422929 Japanese Unexamined Patent Publication No. 2001-097355 Japanese Unexamined Patent Publication No. 2007-168178 Japanese Unexamined Patent Publication No. 2012-21408 Japanese Unexamined Patent Publication No. 2018-094906

When the present inventors examined the speeding up of the laminating process based on the above-mentioned prior art, it became clear that the foam layer had spots and the heat insulating property was lowered.

Further, even if a problem occurs in the laminating process which is a process before foaming, there is a problem that the heat insulating property of the foamed heat insulating paper container sheet can be evaluated unless the polyethylene resin is actually foamed.

That is, the object of the present invention is to provide a sheet for a foamed heat insulating paper container that can be foamed evenly even when laminated at high speed, and to provide a sheet for a foamed heat insulating paper container without going through a foaming step. The purpose is to provide a method for evaluating heat insulation.

The present inventors have improved the heat insulating property of the foamed heat insulating paper container sheet without going through the foaming step by the evaluation method of the foamed heat insulating paper container sheet, which is characterized by measuring the tensile strength of the polyethylene resin in the flow direction. Made it possible to evaluate.

Further, it is a method for manufacturing a sheet for a foamed heat insulating paper container in which a polyethylene resin is laminated on at least one side of a paper base material, the laminating condition is a take-up speed of 70 m / min or more, and the tensile strength of the polyethylene resin in the flow direction is high. The method for manufacturing foamed heat insulating paper container sheets, which is characterized by being 7.0 N / mm ² or less, has made it possible to provide good quality foamed heat insulating paper container sheets even if the laminating process is accelerated. ..

With the completion of the present invention, it is possible to provide a sheet for a foamed heat insulating paper container that can be foamed evenly even when laminated at high speed, and to provide a heat insulating property of the sheet for a foamed heat insulating paper container without going through a foaming step. Can be evaluated.

It is a schematic diagram which showed the aspect of the paper base material at the time of laminating. It is a magnified plan view of the foamed layer when the sheet C1 (prototype example 1) is foamed, and is a standard of "good" in the appearance evaluation. It can be seen that fine and uniform foam cells are present in the foam layer. It is a magnified plan view of the foamed layer when the sheet C2 (prototype example 2) is foamed, and is a standard of "defect" in the appearance evaluation. It can be seen that the foam cells are enlarged and non-uniform.

The present invention is a method for evaluating the foamability of a foamed heat insulating paper container sheet in which a polyethylene resin is laminated on at least one surface of a paper base material without going through a foaming step, and measures the tensile strength of the polyethylene resin in the flow direction. The present invention relates to a method for evaluating a sheet for a foamed heat insulating paper container, which is characterized by the above.

Further, the present invention is a method for manufacturing a foam insulating paper container sheet in which a polyethylene resin is laminated on at least one side of a paper base material, the laminating condition is a take-up speed of 70 m / min or more, and the flow direction of the polyethylene resin. It relates to a method for manufacturing a sheet for a foamed heat insulating paper container, which is characterized in that the tensile strength of the polyethylene is 7.0 N / mm ² or less. The details will be described below.

Paper base material The paper base material constituting the foamed heat insulating paper container sheet of the present invention is not particularly limited, but kraft paper or high-quality paper can be used. Further, from the viewpoint of realizing toughness as a container, the basis weight of the paper base material is preferably 150 to 400 g / m ² , and more preferably 250 to 350 g / m ² . Further, from the viewpoint of preferably foaming polyethylene, the water content in the paper substrate is preferably 5 to 10% by weight, more preferably 6 to 8% by weight.

Further, the paper substrate generally has anisotropy. This is because when the paper base material is manufactured, the paper raw material is squeezed, squeezed, and dried while being pulled in the traveling direction of the production line, so that the paper fibers are arranged in the traveling direction. The direction of travel during paper production is called "paper flow".

Polyethylene resin The polyethylene resin in the present invention is an essential component in the present invention because it is excellent in laminating suitability and foamability. Further, the polyethylene resin in the present invention refers to a low density polyethylene resin (density 910 to 925 kg / m ³ , melting point 105 to 120 ° C.) unless otherwise specified. Medium-density polyethylene resin (density 925 to 940 kg / m ³ , melting point 115 to 130 ° C) and high-density polyethylene resin (density 940 to 970 kg / m ³ , melting point 125 to 140 ° C) have high melting points and poor foamability. Not normally used in foaming applications.

Further, the melt tension (hereinafter, may be referred to as “MS”) of the low-density polyethylene resin at a temperature of 130 ° C. and a take-up speed of 10 m / min is preferably 70 to 120 mN, and more preferably 80 to 100 mN. When the melt tension is less than 70 mN, neck-in tends to occur, so the melt tension of the polyethylene resin is preferably 70 mN or more, and more preferably 80 mN or more.

The neck-in is a phenomenon in which the width of the extruded polyethylene resin film becomes too small compared to the effective width of the T-die when the polyethylene resin is extruded into a film by a T-die extruder. If the film width is only narrowed, it can be dealt with by widening the effective width of the T-die, but if the neck-in is severe, the thickness of both ends of the polyethylene resin film will increase, and it will be discarded to remove this part. The amount increases and productivity drops significantly.

On the other hand, when the melt tension exceeds 120 mN, the polyethylene resin tends to be oriented at the time of laminating, and the foamed appearance tends to deteriorate. Therefore, the melt tension of the polyethylene resin is preferably 120 mN or less, and more preferably 100 mN or less.

The melt flow rate of the polyethylene resin (hereinafter, may be referred to as “MFR”) is preferably 8 to 28 g / 10 minutes, more preferably 10 to 20 g / 10 minutes. Within this range, the polyethylene resin can be stably foamed, so that the heat insulating property and the appearance after foaming are good.

Extrusion Laminating Conditions As the extrusion laminating method, a single laminating method, a tandem laminating method, a sandwich laminating method, a co-extruded laminating method, or the like can be appropriately selected.

The temperature of the polyethylene resin (immediately below the T die) at the time of laminating is preferably 260 to 350 ° C, more preferably 280 to 330 ° C. Within this range, the lamination strength between the polyethylene resin layer and the paper substrate and the appearance after foaming can be made suitable. Further, it is preferable to control the surface temperature of the cooling roll in the range of 10 to 50 ° C.

The thickness of the polyethylene resin layer after laminating (before foaming) is not particularly limited, but is preferably 30 to 150 μm, more preferably 40 to 100 μm. Within this range, the polyethylene resin layer after foaming can have a sufficient thickness, so that the heat insulating property is good.

The pick-up speed in the present invention is preferably 130 m / min or less, more preferably 110 m / min or less. This is because if the take-up speed is too fast, the polyethylene resin tends to neck in and the productivity decreases.

Next, the air gap will be described. Here, the air gap refers to the distance from the T-die extrusion port to the nip roll.

The air gap during laminating is preferably 150 mm or more, more preferably 160 mm or more. Although the details will be described later, by expanding the air cap, it is possible to laminate while retaining the oxide film formed on the polyethylene resin surface, so that a good foam layer can be realized.

On the other hand, if the air gap is widened too much, the polyethylene resin will neck in and the productivity will decrease. Therefore, the upper limit of the air gap is preferably 250 mm or less, more preferably 200 mm or less.

Although the details of this mechanism are not clear, the present inventors presume as follows.
An oxide film is formed on the surface of the polyethylene resin as the resin passes through the air gap. Since this oxide film is tougher than the inner polyethylene resin layer, it is possible to suppress partial hyperfoaming and realize a uniform foamed layer. Therefore, it is important to laminate while retaining the oxide film.

On the other hand, the oxide film tends to disappear mainly when the polyethylene resin is stretched with a nip roll. Specifically, it is considered that the oxide film disappears when the oxide film is cut or mixed with the resin inside because the force for stretching the resin and the force for pushing the resin are instantaneously applied at the time of niping.

As a method of retaining the oxide film, a method of lowering the take-up speed can be considered. When the take-up speed is lowered, the speed of the nip roll is also slowed down, so that the force is applied slowly, and the oxide film can be stretched while being retained. However, there is a problem that productivity is lowered when the pick-up speed is lowered.

Generally, the thickness of the polyethylene resin extruded from the T die is not uniform, the thickest immediately after being extruded from the T die, and the thinnest immediately before being nipped. Further, when the air gap is widened, the thickness of the polyethylene resin immediately before the nip becomes even thinner than before the air gap is widened. Therefore, by widening the air gap, the thickness of the polyethylene resin immediately before the nip becomes thin, and the force applied to the polyethylene resin at the time of niping becomes slow, so that the disappearance of the oxide film can be suppressed.

Next, the air gap transit time will be described. Here, the air gap passage time refers to the time for the polyethylene resin extruded from the T die to pass through the air gap.

The lower limit of the air gap passage time is preferably 0.08 seconds or more, more preferably 0.10 seconds or more. As described above, in order to realize a uniform foam layer, an oxide film formed on the polyethylene resin surface is important, but if the air gap passage time is too short, it is difficult to form an oxide film. When a sufficient air gap passage time cannot be secured (for example, 0.04 seconds), the same effect as extending the air gap passage time can be realized by treating with ozone gas and / or oxygen gas.

The upper limit of the air gap passage time is preferably 0.30 seconds or less, more preferably 0.20 seconds or less. If the air gap passage time is too long, the polyethylene resin will neck in and the productivity will decrease, which is not preferable.

In the present invention, it is preferable to surface-treat the polyethylene resin with ozone gas and / or oxygen gas while passing through the air gap. By surface-treating with ozone gas and / or oxygen gas, the formation of an oxide film can be promoted and the adhesive force with the substrate layer can be improved. The amount of ozone gas and / or oxygen gas to be treated is not particularly limited, but 0.5 mg / m ² or more is preferable from the viewpoint of promoting the oxidation of the polyethylene resin.

Tensile strength in the flow direction First, the tensile strength (N / mm ² ) in the present invention refers to the mechanical strength obtained by the force required to break the polyethylene resin when it is pulled, and is required at the time of breaking. It is calculated by dividing the force (N) by the cross-sectional area (mm ² ).

Next, the tensile strength in the flow direction (MD: machine direction) (hereinafter, may be referred to as “MD strength”) is the tensile strength of the polyethylene resin cut out along the flow direction of the laminating process. The direction perpendicular to the flow direction is called a vertical direction (TD: transverse direction).

Next, the relationship between the formation of the oxide film and the MD strength, which is a parameter of the present invention, will be described.

The strong MD strength indicates that the orientation of the polyethylene resin is strong. The strong orientation is an indicator that the polyethylene resin is pulled during laminating and the oxide film disappears. Therefore, by keeping the MD strength low, it is possible to realize a suitable foam layer in the subsequent foaming step even when laminating at a high speed when manufacturing a sheet for a foamed heat insulating paper container.

Specifically, the tensile strength of the polyethylene resin in the flow direction is preferably 7.0 N / mm ² or less, and more preferably 6.0 N / mm ² or less. If the tensile strength in the flow direction exceeds 7.0 N / mm ² , the cells tend to become bloated and non-uniform during foaming.

The low-density polyethylene resin used in this example is as follows.
Medium density polyethylene resin (A1): Tosoh's "Petrosen LW04-1", MFR 6.5g / 10 minutes, density 940kg / m ³
Low density polyethylene resin (B1): "Novatec LC701" manufactured by Japan Polyethylene Corporation, MFR 15g / 10 minutes, density 918kg / m ³
Low density polyethylene resin (B2): Tosoh's "Petrosen 07C03C", MFR 15g / 10 minutes, density 918kg / m ³

Prototype example 1
(Step 1) A medium-density polyethylene resin (A1) was extruded and laminated on one side of a paper substrate to form a water vapor blocking layer. (Step 2) Next, a low-density polyethylene resin (B3) was extruded and laminated on the non-laminated surface to form a foamed layer, and a foamed heat insulating paper container sheet C1 (hereinafter referred to as “sheet C1”) was manufactured. The details of the laminating conditions are as follows.

(Step 1)
Paper substrate: Moisture content 23 g / m ² , Basis weight 320 g / m ²
Medium density polyethylene resin (A1): Tosoh's "Petrosen LW04-1", MFR 6.5g / 10 minutes, density 940kg / m ³
Extrusion temperature (T die outlet temperature): 320 ° C
Pick-up speed (lamination speed): 80m / min Air gap: 130mm
Air gap passage time: 0.10 seconds Thickness: 40 μm (thickness of the central part of the polyethylene resin layer)

(Step 2)
Low density polyethylene resin (B1); melt tension (temperature 130 ° C, take-up speed 10 m / min) 93 mN
Extrusion temperature (T die outlet temperature): 310 ° C
Pick-up speed (lamination speed): 60m / min Air gap: 155mm
Air gap passage time: 0.16 seconds Thickness: 70 μm (thickness of the central part of the polyethylene resin layer)

In Prototype Example 1, the sheets C2 to C4 were manufactured by changing the low density polyethylene resin, the air gap, and the take-up speed as shown in Table 1.

The sheets C1 to C4 were heated at 120 ° C. for 6 minutes and foamed to evaluate the appearance of the foamed layer. The evaluation conditions are as follows.

(Appearance evaluation)
The surface of the foam layer was observed using a stereomicroscope (“MULTIZOOM AZ100M (camera: DS-Ri1)” manufactured by Nikon Corporation). At this time, the case where fine and uniform foam cells equal to or finer than Sheet C1 (Prototype Example 1, see FIG. 2) are observed is “good”, and Sheet C2 (Prototype Example 2, see FIG. 3) shows. When such a large and non-uniform foam cell was observed, it was evaluated as "defective".

Next, the MD intensity was measured. The measurement method is as follows.
(1) Sample acquisition A PET film was attached to a paper substrate, and a low-density polyethylene resin (LDPE) was laminated therein. The PET film was peeled off from this laminate (PET / LDPE laminate) to obtain an LDPE film (50 μm).

The low-density polyethylene resin film was produced at the same time as the sheets C1 to C4 were produced. Taking a schematic diagram (FIG. 1) as an example, the foamed appearance is evaluated in the region 1, and the PET / LDPE laminate is formed in the region 2.

(2) Preparation of test pieces
Ten test pieces of LDPE film cut out in the flow direction were prepared.
Test piece for MD strength measurement: 15 mm (vertical direction) x 150 mm (flow direction)

(3)
The tensile strength (N / mm ² ) was measured with a tensile strength measuring instrument (“Tencilon RTC-1310A” manufactured by A & D Co., Ltd., load cell 100N). Table 2 shows the average value of the tensile strength.
Environmental conditions: 25 ° C, 55% RH
Distance between chucks: 100 mm
Tensile speed: 100mm / min

From the above results, it can be seen that the evaluation of the foamed appearance corresponds to the MD strength. Therefore, by this method, it is possible to evaluate the heat insulating property of the foamed heat insulating paper container sheet without going through the foaming step.

(Explanation of code)
10 Paper base material 10a Paper flow direction MD Polyethylene resin flow direction (MD)
TD Direction perpendicular to the flow direction of polyethylene resin (TD)
20 PET film 30 Area 1
31 Area 2 (for measuring tensile strength)

Claims (5)

A method for evaluating the foamability of a foam-insulated paper container sheet in which a polyethylene resin is laminated on at least one side of a paper base material without going through a foaming process.
Measuring the tensile strength of polyethylene resin in the flow direction,
A method for evaluating a sheet for an effervescent heat insulating paper container. The method for evaluating a foam-insulated paper container sheet according to claim 1, wherein a criterion for good foamability is set to a tensile strength of 7.0 N / mm ² or less in the flow direction of the polyethylene resin. A method for manufacturing a sheet for an effervescent heat insulating paper container in which polyethylene resin is laminated on at least one side of a paper base material.
Laminating conditions are a pick-up speed of 70 m / min or more,
and,
The tensile strength of the polyethylene resin in the flow direction is 7.0 N / mm ² or less.
A method for manufacturing a sheet for an effervescent heat insulating paper container. The method for manufacturing a sheet for a foamed heat insulating paper container according to claim 3, wherein the tensile strength of the polyethylene resin in the flow direction is 6.0 N / mm ² or less. The method for manufacturing a sheet for a foamed heat insulating paper container according to claim 3 or 4, wherein the thickness of the polyethylene resin after laminating is 30 to 150 μm.

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