KR930001726Y1 - Heat-resistant synthetic resin bottle - Google Patents

Abstract

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Description

Heat resistant plastic bottle

The present invention relates to a heat resistant bottle having biaxial orientation, and in particular, to a bottle having a heat resistant bottom portion prepared by stretching and blow molding of a thermoplastic resin such as polyethylene terephthalate. .

(Prior Art)

Self-supporting bottles, which can prepare preformed products made of polyethylene terephthalate by axial stretching and air blowing, are more durable than heated bottles by blow molding, but When filling the contents, the stretched and air blown bottles must be heat treated to avoid shrinkage or deformation by the heat received during the filling step.

This heat treatment is effective for the body part and bottom peripheral wall of the bottle with biaxial orientation, but it is impossible to make thermal stability even the bottom wall. Therefore, most of the bottles have low thermal stability, so that thermal deformation occurs in the bottom bed.

The heat resistance of this bottom wall is thought to be improved by having sufficient biaxial orientation also in the bottom deformation. However, from the point of view of the bottom structure, it is difficult to have a sufficiently biaxial orientation in the center portion of the bottle having a draw ratio limit.

Although biaxial directionality is obtained, the bottom wall, which must enter in to improve its self-supporting properties, will become thinner and expand out of its load when filling the contents, resulting in the bottle's self-supporting ability. This is lost.

The self-supporting bottom structure, commonly referred to as the bottom of the siamese bottle, enters the bottle body 1 together with the peripheral wall 12 which is sufficiently biaxially oriented and the bottom surface 13 which is continuous. It is molded into the shape of a dome as illustrated in FIG.

Supporting the bottle 1 itself is achieved by an annular perimeter 14 formed between the perimeter wall 12 and the bottom wall 13.

In such a bottom structure, the bottom portion 16a of the parison 16 when the bottle 1 is molded in the blow mold 15 by axial stretching and air blowing the parison. Will be in contact with the mold bottom 17 before the other part and will cool.

Moreover, the draw ratio of the parison bottom part will be smaller because of the structure of the mold bottom part 17. Thus, the bottom face 13 having a dome shape will form a thick wall with its central portion 13a as shown in FIG. Biaxial directionality will be established only at the thinly annular periphery 14 which extends sufficiently and the peripheral portion 13 adjacent thereto.

In the bottom portion having the above-described structure, the portion 13c which is not sufficiently biaxially oriented and is a relatively thin wall is easily deformed by heat.

The central portion 13a is also deformed by heat.

However, with a thick wall, it will tolerate some of the effects of heat and prevent the bottom wall from severely deforming.

In any case, the poor directional portion 13c is thinner than the central portion 13a.

Therefore, significant deformation will occur when the bottle is filled with contents heated to a temperature above 75 ° C. Portion 13c will be pushed out of annular end 14 when a load is applied.

Such a phenomenon impairs the bottle's ability to support itself, and although there is no such damage, it is clear that the shape of the bottle is deformed unfavorably and reduces its commodity value.

As a means for imparting heat resistance by achieving sufficient biaxial directionality to the portion 13a which lacks the directionality and is easily affected by heat, hollow ribs 15 (rib) indicated by chain lines in the middle portion of the bottom wall 13 are molded. It is.

In most cases, however, such a lip 15 would be pushed towards the wall of the domed bottom wall 13 due to straight or blow molding limitations. In a word, the lip 15 is not shaped to prominently protrude from the wall surface.

As a result of the molding of such a lip 15 which is slightly pushed in, the bottom area required for biaxial directionality only increases slightly.

Therefore, the central portion 13a in contact with the lip 15 is not stretched sufficiently even if the peripheral portion 13b in contact is sufficiently stretched and thus maintains a thick state. For this reason, the functional effect of the lip only improves heat resistance for the peripheral portion 13b of the bottom wall 13, and the above-described portion 13c which is sensitive to the influence of heat cannot have heat resistance.

Thus, although the lip 15 is molded, the bottle will deform when filled with the heated contents.

(Summary of design)

The object of the present invention is to provide heat resistance to the bottom wall of a heat resistant plastic bottle that is susceptible to deformation when filled with heated contents.

Another object of the present invention is to improve the formation of a plurality of hollow protrusions of a specific shape in the middle portion of the bottom wall, which is not sufficient in biaxial direction, is thinner than the center portion of the bottom wall, and is therefore very sensitive to heat.

In addition, another object of the present invention is to stretch and direct the central portion of the bottom wall that is easy to be molded thick, and to provide a plurality of hollow lugs on the middle of the bottom wall heat-resistant synthetic resin to prevent the heat-fever type often caused on the bottom wall To provide a bottle.

The present invention according to the object relates to a synthetic resin bottle having a support ability, and performs molding by making a parison with the inserted or protruding end closed by blow molding in the axial direction and air blowing. Whereby the bottom wall of the bottle enters inwardly into the dome shape and the annular circumference is formed at the bottom of the bottle and the top of the bottom wall gradually formed thickly from the annular main right end to the center part is normal. In order to thin the part, it was recessed from below the top part to the upper part, and the middle part of the bottom wall was partially inflated to form radially the protrusion of the sufficiently thin triangular pyramid-shaped hollow wall The middle portion of the is characterized in that the thermal deformation can be prevented.

(Detailed description of the proposal)

1 to 3, reference numeral 1 denotes a biaxially oriented bottle body molded by stretching and blow molding polyethylene terephthalate. The bottom of the bottle body 1 has a sufficient biaxial circumferential wall 2, an annular circumferential end 4, which is the boundary between the circumferential wall 2 and the bottom wall 3, and a dome shaped recessed into the bottle. It consists of the bottom wall 3.

The bottom wall 3 is molded to be thickened gradually from the connecting portion to the annular end 4 at the central portion thereof, and the top portion 3a is molded to dent upward from the bottom surface to the top portion.

In the part 3c where the directionality between the top part 3a and the peripheral part 3b adjacent to the annular circumferential end 4 is not sufficient, the bottom wall part is partially expanded and formed at regular intervals, There are radially arranged triangular pyramidal shaped hollow thin wall protrusions 5, 5 and between the pair of hollow protrusions 5, 5 is the bottom armature 6, 6 of the bottom wall 3.

The ridge 5a connecting the top portion 3a and the tip of each hollow protrusion 5 may have an angle in the range of 30 ° to 90 ° with respect to the horizontal plane.

If this angle is less than 30 °, the floor area where sufficient stretching is achieved will decrease.

Moreover, the effect of improving the part 3 by biaxial orientation cannot be expected.

In each hollow projection 5, the bottom surface 5b is molded thinly similar to the peripheral portion 3b. However, the side surface 5c of the protruding boom 5 gradually thickens toward the top portion 3a together with the ridge portion 5a. The number of hollow protrusions 5 depends on the size of the floor area, and in the embodiment shown in the drawing, five hollow protrusions 5 serve to improve the bottom wall 3 but six protrusions 5 may be provided. have.

In relation to a bottle having such a bottom structure, all the other portions 3c except the bottom skeletons 6 and 6 have biaxial orientation, and only the bottom skeletons 6 and 6 tend to be thermally deformed.

In any case, since these bottom frames 6,6 are between the triangular pyramidal hollow projections 5,5, the occurrence of thermal deformation is limited only to this localized portion and will not spread to the front floor wall.

Furthermore, even though each hollow protrusion 5,5 is stretched to a thin wall state, the load of the contents of the bottle is supported by both side walls 6 and 6 of the thick wall bottom skeleton 6 and 6, respectively. .

Thus, the bottom wall 3 will not protrude outwardly from the annular circumferential end 4 even if a load is applied to the hollow protrusions 5 and 5, unless the bottom armatures 6 and 6 are broken.

Moreover, in the past, when the bottle filled with contents fell, it was destroyed at the center of the bottom wall 3. Because this central part is thick.

In the case of the present invention, since the top part is thinly stretched as described above, the destruction of the bottle at the center part can be prevented, and this fact improves the impact resistance.

3 shows another embodiment of a bottle having bottom skeletons 6, 6 stretched biaxially. In this embodiment, the molding of the outwardly expanding hollow projections 5, 5 can be easily obtained by allowing the bottom armature portions 6, 6 of the bottom wall 3 to enter inwards.

As understood from the foregoing, according to the present invention, thermal deformation and deformation due to load of the bottom wall can be prevented and the bottle according to the present invention can maintain the self-supporting function even if the bottle is filled with high temperature contents.

Moreover, the expanded top and the triangular pyramidal hollow protrusions can be easily molded by the use of a blow mold, so that the increase in cost can be limited.

1 is a cross-sectional view of the bottom of the heat-resistant synthetic resin bottle according to the present invention.

2 is a plan view of FIG.

3 is a vertical cross-sectional view of the bottom of another embodiment according to the present invention.

4 is a vertical sectional view of the bottom of a conventional self supporting bottle.

(Design background)

Claims (2)

Molding is performed by inserting or protruding the closed parison into the blow mold by axial stretching and air blowing, thereby making the bottom wall 3 of the bottle 1 dome shaped. In the heat-resistant synthetic resin bottle (1) in which an annular periphery (4) is formed around the bottom wall (3) to dent into it and support the diseased body, from the periphery (4). The top portion of the bottom wall, gradually thickened into its central portion 3a, dents from below the top portion itself to make the top portion thin, and between the top portion and the peripheral end 4 The bottom wall 3 is heat-resistant, characterized in that it partially expands out to form a predetermined number of triangular pyramidal hollow projections 5 and the bottom armature between the hollow projections 5 in the radial direction. Plastic bottles. 2. Heat resistance according to claim 1, characterized in that the bottom (5b) of the triangular pyramidal hollow projections (5) is a thin wall and the opposing side surfaces (5c) of each projection are gradually thickened towards its ridge (5a). Plastic bottles.