Method of making heat-resistant transparent container

FIELD OF THE INVENTION

This invention relates to heat-resistant transparent containers, especially food containers for convenience stores etc., wherein food is placed therein and sold, or for retort sterilization, and more particularly, relates to the heat-resistant transparent containers having heat-resistance without deformation even at 150° C. reached by heating foods containing oils by a microwave oven or at 125° C. which is a retort sterilization temperature, and having excellent transparency.

BACKGROUND OF THE INVENTION

In food shops in convenience stores, department stores, super markets, etc., foods, such as daily dishes, noodles and salads, are placed in food containers, e.g., tray, cup or bowl, and sold. Such a food container is composed of a container body and a cover. The container body is, in general, manufactured by thermoforming a sheet of polypropylene, foamed polypropylene, filler-containing polypropylene, polyethylene, foamed polyethylene, formed polystyrene, foamed heat-resistant polystyrene, amorphous polyethylene terephthalate (A-PET), etc, by a vacuum forming machine, a pressure forming machine or a vacuum-pressure forming machine. The cover is formed from a sheet, such as A-PET, biaxially oriented polystyrene (OPS) or polypropylene (PP) (JP2005-329972A).

Recently, it is frequently conducted that foods packaged in a food container are bought and heated as it is by a microwave oven. When foods containing oils are heated together with the food container by a microwave oven, temperature of the foods is raised to around 150° C. Accordingly, food containers are required to have high heat resistance resisting up to 150° C. Even in the case of food not containing oils, food containers for retort foods are required to resist a retort sterilization temperature at 125° C. Furthermore, food containers are desirably to have high transparency so that the foods packaged therein can be appreciated clearly at a look and can improve commercial value.

However, none of the above-mentioned conventional sheets satisfies both of high heat resistance and high transparency. That is, A-PET and OPS have high transparency, but have not high heat resistance and are softened at around 80° C. PP sheet has high heat resistance but is inferior in transparency.

SUMMARY OF THE INVENTION

It is an object of the invention to provide a food container having high transparency and high heat resistance.

The inventors investigated eagerly in order to solve the above problems and noted A-PET sheet and OPS sheet having high transparency. However, OPS sheet has anxiety in safety and hygiene caused by elution of residual monomer, dimer and trimer and additives. Then, they examined to improve heat resistance of A-PET which is excellent in safety and hygiene for food.

As a result of investigation, they found that high heat resistance capable of resisting a temperature of 150° C. can be imparted to A-PET by the crystallization through stretching and heat-setting to complete the invention.

Thus, this invention provides a method of making a heat-resistant transparent container which comprises:

a primary stretching and heat-setting process wherein an amorphous polyethylene terephthalate sheet is heated, primarily stretched and then primarily heat-set, and

a secondary stretching and heat-setting process wherein the sheet treated in the primary stretching and heat-setting process is molded with heating in a mold of a thermoforming machine while secondary stretching is performed followed by secondary heat-setting in the same mold.

In the invention, in the primary stretching and heat-setting process, crystallinity of A-PET sheet is raised within the range capable of thermoforming, and in the secondary stretching and heat-setting process, the sheet treated in the primary stretching and heat-setting process is molded into a shape of container and crystallinity is further raised to improve heat resistance. Besides, in the primary stretching and heat-setting process, since A-PET sheet is stretched followed by heat-setting, a cheap apparatus can be applied. In the secondary stretching and heat-setting process, since a clear and heat-resistant molded body can be obtained by heat-setting in the same mold, the apparatus therefor is cheap due to not conducting double molding. Moreover, molding time can be shortened to raise productivity.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic illustration of an apparatus for manufacturing a longitudinally uniaxially stretched A-PET sheet.

FIG. 2 is a schematic illustration of a thermoforming apparatus.

FIG. 3 is a perspective view of thermoformed article.

FIG. 4 is a schematic DSC chart.

- 1 . . . A-PET sheet
- 2 . . . Preheating roll
- 3 . . . Nip roll
- 4 . . . Heating roll
- 5 . . . Stretching roll
- 6 . . . Heat-setting roll
- 7 . . . Longitudinally uniaxially stretched A-PET sheet
- 11 . . . Upper heating plate
- 12 . . . Lower heating plate
- 13 . . . Upper mold
- 14 . . . Lower mold
- 15 . . . Embedded heater
- 16 . . . Thermoformed article

DETAILED DESCRIPTION OF THE INVENTION

The amorphous polyethylene terephthalate (A-PET) sheet is fundamentally in non-(or slight) crystalline state having a crystallinity of approximately 5 to 7%. The A-PET sheet is not stretched and is commercially available. A typical thickness of the A-PET sheet is 0.2 to 1.5 mm, particularly 0.3 to 1.0 mm, though it varies according to the container to be made. Although the resin of the A-PET sheet is not necessary to have a high intrinsic viscosity, when the intrinsic viscosity of the resin is 0.6 dl/g or less or the resin is obtained from flakes of recovered PET bottles, it is possible that surface conditions are not good. In these cases, a pretreatment is necessary.

In the primary stretching and heat-setting process, the A-PET sheet is heated and primarily stretched by uniaxial stretching. The A-PET sheet may be either previously molded (stocks) or molded in-line by a T-die molding machine.

A suitable stretching temperature (surface temperature of the A-PET sheet) in the primary stretching is in the range from 90 to 120° C., preferably 95 to 110° C. When the stretching temperature is lower than 90° C., tension loaded is great while stretching the A-PET sheet, and thickness of stretched A-PET sheet tends to be not uniform caused by uneven stretching. When the stretching temperature exceeds 120° C., the sheet is whitened and surface roughening also occurs.

A suitable draw ratio is 2 to 5 times, preferably 2.6 to 3.7 times. When the draw ratio is less than twice, cold crystallization point is observed in the measurement by a differential scanning calorimeter (DSC). Crystallinity becomes less than 22%, and thermoformed article formed in the later thermoforming process is whitened. When the draw ratio exceeds 5 times, slip tends to occur on stretching roll during stretching, and lateral wave patterns generate caused by the presence of slipped portions and non-slipped portions.

A typical stretching apparatus is a uniaxial stretching apparatus using heating rolls, which may be single step stretching in a short range or multiple step stretching of two or more steps.

The primary heat-setting temperature is not specifically limited, but in view of relaxation of orientation by annealing, a preferred temperature is higher than the stretching temperature by 5 to 20° C. When the heat-setting temperature is lower than the above range, i.e., not higher than the stretching temperature plus 5° C., heat shrinkage of the sheet is great. When the heat-setting temperature is higher than the above range, i.e., exceeding the stretching temperature plus 20° C., surface roughening occurs to be slightly whitened. More preferable temperature range is stretching temperature plus 5° C. to 15° C., because heat shrinkage is small to render deformation on molding of thermoformed body.

The heat-setting time is usually 1.5 to 2.0 seconds, preferably 2 to 15 seconds. In order to meet the relaxation of orientation of the sheet, rotational speed of heat-setting roll is made slower than the stretching roll by about 0.5 to 10%.

Such a primarily stretched A-PET sheet after the primarily heat-setting is preferably to have a crystallinity of 22% or more and less than 30%. In the crystallinity of less than 22%, since cold crystallization point exists, it is possible to be whitened upon heating in the secondary stretching. Exceeding 30%, thermoforming is made difficult to degrade reproducibility. The crystallinity is represented by the formula:
$crystallinity (%) = \frac{(\begin{matrix} quantity of heat of \\ fusion per mole \end{matrix}) - (\begin{matrix} quantity of heat of cold \\ crystallization per mole \end{matrix})}{\begin{matrix} quantity of heat of fusion of perfect \\ crystal PET per mole (26.9 kj) \end{matrix}} \times 100$

The sheet treated in the primary stretching and heat-setting process desirably has a crystallinity of 22% or more and less than 30%. By rendering the crystallinity in the above range, thermoforming in the secondary process can be achieved smoothly, and the crystallinity is brought close to the range of 30% or more where high heat resistance is obtained in the secondary stretching and heat-setting process.

In the secondary stretching and heat-setting process, the sheet treated in the primary stretching and heat-setting process is molded with heating in a mold of a thermoforming machine while secondary stretching is performed, followed by secondary heat-setting in the same mold.

The second stretching is practiced while molding. A suitable secondary stretching temperature, i.e. molding temperature, is 80 to 130° C., preferably 90 to 120° C. When the stretching temperature is lower than 80° C., waviness occurs on thermoformed articles. When the stretching temperature exceeds 130° C., drawdown of the sheet increases to generate wrinkle on thermoformed articles.

The type of the thermoforming machine may be vacuum molding type, pressure forming type or vacuum-pressure forming type.

After the molding in the mold, heat-setting is carried out in the same mold. A suitable temperature for the secondary heat-setting is 160° C. or higher, preferably 170° C. or higher. When the heat-setting temperature is lower than 160° C., it is liable not to ensure heat resistance at 150° C. Although there is no upper limit to the heat-setting temperature, when heat-setting is carried out at a temperature higher than 220° C. for a long time, thermoformed articles are liable to be whitened and translucent.

The heat-setting time in the mold is 7 seconds or more, preferably 10 seconds or more. When the heat-setting time is shorter than 7 seconds, wave-formed wrinkle tends to occur on the molded article.

It is necessary that the A-PET sheet treated in the secondary stretching and heat-setting process, which is a thermoformed article, has a crystallinity of 30% or more for imparting a heat resistance to 150° C. Thermoformed articles having a crystallinity of less than 30% are inferior in heat resistance. The crystallinity of 30% or more can be achieved with keeping good transparency by molding the sheet treated in the primary stretching and heat-setting process at a temperature of 80 to 130° C. while secondary stretching is carried out and then heat-setting at a temperature of 160° C. or more.

The heat-resistant transparent container of the invention can be applied to various containers of which heat resistance and transparency are required, and is suitable for food containers, especially for the food containers heated by a microwave oven or for retort food containers.

A process for manufacturing the heat-resistant transparent container according to the invention will be explained with reference to drawings.

In FIG. 1, A-PET sheet 1 is delivered from its storage roll, and preheated to 70 to 90° C. while passing preheating rolls 2 nipped by nip rolls 3. Then, the sheet 1 is further heated to 90 to 120° C. by heating rolls 4 nipped by nip rolls 3, and stretched 2 to 5 times by stretching rolls 5 in the longitudinal direction. The uniaxially stretched A-PET sheet 1 is heated by heat-setting rolls 6 to a temperature higher than the temperature heated by heating rolls 4 by 5 to 20° C. to be heat-set to complete a longitudinally uniaxially stretched A-PET sheet 7.

As shown in FIG. 2, the longitudinally uniaxially stretched A-PET sheet 7 is located between upper heating plate 11 and lower heating plate 12 to be heated to 80 to 130° C. as the surface temperature of the sheet, and thermoformed by pressing by upper mold 13 and lower mold 14. The thermoformed sheet is kept for 10 seconds in the pressed state, and then, taken out. Since lower mold 14 is heated by embedded heaters 15 to 160° C. or more, the thermoformed article 16 is heat-set at 160° C. A thermoformed article is shown in FIG. 3.

EXAMPLES
Example 1

An A-PET sheet 0.4 mm thick (crystallinity: 6.1%, manufactured by ATHENA-KOGYO Co., Ltd.) was stretched by a roll type uniaxially stretching machine (“T-17” type, manufactured by NIPPON SEIKO SHO, Ltd.). The stretching conditions were set the preheating roll temperature at 80° C., the heating roll temperature (stretching temperature) at 95° C., the stretching roll temperature at 80° C. and the heat-setting roll temperature at 100° C. The A-PET sheet was delivered at a speed of 3 m/mim., and stretched 2.6 times by the stretching rolls 5. The stretched sheet was heat-set for 10.5 seconds while passing through the heat-setting rolls 6 to obtain a stretched A-PET sheet 0.15 mm thick.

The stretched A-PET sheet was transparent and no wrinkle. The crystallinity determined by a differential scanning calorimeter (DSC) was 24%, and no cold crystallization peak was observed.

Subsequently, the stretched A-PET sheet was heated by heaters so that the surface temperature became 90° C. The softened stretched A-PET sheet was molded by vacuum-pressure forming using a vacuum-pressure forming machine (“FKC” type, manufactured by ASANO LABORATORIES, Ltd.) at an air pressure of 0.5 MPa. The served mold was a cavity type aluminum mold having an upper diameter of 180 mm×95 mm, a bottom diameter of 165 mm×75 mm and a depth of 15 mm, and the temperature of the aluminum mold was set at 180° C. The heat setting time was 10 seconds.

The thermoformed article kept the transparency of the stretched A-PET sheet, and had a shape in accordance with the mold without deformation. The crystallinity was 30.5%.

The thermoformed article was subjected to heat resistance test by microwave oven heating. In the heat resistance test, a pork cutlet was put on the thermoformed article, and heated by a microwave oven (“National NE-EZ2”) at 700 W for 3 minutes. The surface temperature of the heated pork cutlet was measured by an infrared radiant thermometer (“SATO SK-8700II”), and found to be 157° C. Oils pooled at the bottom of the thermoformed article. The thermoformed article was kept transparent without deformation.

Example 2

An A-PET sheet 0.6 mm thick (crystallinity: 6.3%, manufactured by ATHENA-KOGYO Co., Ltd.) was stretched by the same stretching machine under the same conditions as Example 1, except that the draw ratio was 3 times to obtain a stretched A-PET sheet 0.2 mm thick.

The stretched A-PET sheet was transparent and no wrinkle. The crystallinity determined by DSC was 28.9%, and no cold crystallization peak was observed.

Subsequently, the stretched A-PET sheet was molded by vacuum-pressure forming using the same apparatus and the same conditions as Example 1 to obtain a thermoformed article.

The thermoformed article kept the transparency of the stretched A-PET sheet, and had a shape in accordance with the mold without deformation. The crystallinity was 34.2%.