JP2005075408A - Synthetic resin bottle container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a synthetic resin bottle container, which ensures a pressure reduction absorptivity efficiently even if a large area for pressure reduction absorbing panels cannot be secured. <P>SOLUTION: A PET bottle 100 has a trunk 130 on which the pressure reduction absorbing panels 170 are formed. The panels 170 are sank vertically to the inside of the trunk 130 toward a plane F including the bottle axis O1 and the bottle radial axis O2. The bottle 100 is also provided with a side wall 180, which connects the ends 170e of the panels 170 to the trunk 130. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a synthetic resin bottle-type container including a vacuum absorption panel in a body portion of a container.

  Synthetic resin bottle-type containers are collectively referred to as so-called PET bottles made of polyethylene terephthalate (PET), and in recent years, small-sized containers of 500 ml (milliliter) or less have become widespread. Also, in the case of filling a high-temperature content in a PET bottle or the like, the inner pressure of the bottle is reduced, so-called a reduced pressure state, so that the barrel portion has a vacuum absorption capacity basically required as a heat-resistant bottle. A countermeasure is taken to prevent deformation of the bottle by providing a reduced pressure absorption panel.

  However, as the inner volume of the bottle becomes smaller, such as 350 ml (milliliter), 300 ml (milliliter), and 200 ml (milliliter), naturally, the surface area of the body portion also becomes smaller, so it is difficult to secure the area of the vacuum absorbing panel. It has become to. Such a decrease in the area occupied by the vacuum absorbing panel leads to a shortage of vacuum absorbing capacity, and in addition to a decrease in bottle rigidity, in the worst case, the appearance of the bottle is deformed and the product value at the store is impaired. .

  On the other hand, in the so-called square bottle in which the body portion of the container is formed in a rectangular tube shape, two parts are formed on one side of the body portion so as to compensate for the shortage of the reduced pressure absorption capacity accompanying the decrease in the area occupied by the reduced pressure absorption panel. There has been proposed a structure in which a reduced-pressure absorption panel is vertically divided along a bottle central axis, and these reduced-pressure absorption panels are connected by at least one groove (for example, see Patent Document 1).

JP 2000-238736 A

  However, as a result of many years of research and development, the inventor of the present application has found that there is still room for improvement in securing the reduced pressure absorption capacity even in the conventional bottle with such measures.

  The present invention has been made in view of these facts, and provides a synthetic resin bottle-type container that can efficiently secure a reduced pressure absorption capacity even when the area of the reduced pressure absorption panel cannot be increased. Objective.

  The invention according to claim 1 is the bottle made of a synthetic resin provided with a vacuum absorption panel in the body of the container, wherein the vacuum absorption panel is placed inside the body toward a plane including the bottle center axis and the bottle radial axis. A side wall is provided that drops vertically and connects the end of the reduced pressure absorption panel and the body.

  According to a second aspect of the present invention, in the first aspect, the central portion of the reduced pressure absorption panel includes a protrusion having a flat top surface.

  According to a third aspect of the present invention, in the second aspect of the present invention, the step from the side wall to the rising portion of the protruding portion is formed in a stepped shape along the circumference of the container.

  According to the first aspect of the present invention, the vacuum absorption panel is dropped vertically inside the barrel toward the plane including the bottle center axis and the bottle radial direction axis, and between the end of the vacuum absorption panel and the barrel. Since the decompression absorption panel moves better and the decompression absorption capacity is increased by the movable body integral of the sidewall, the degree of decompression can be suppressed even when the area of the decompression absorption panel cannot be increased. At the same time, the vacuum absorption capacity necessary to prevent the deformation of the bottle-type container can be efficiently ensured. Therefore, according to the invention which concerns on Claim 1, the small bottle type container which was excellent in heat resistance and cannot change easily can be provided.

  Since the invention which concerns on Claim 2 is provided with the protrusion part which has a flat top surface in the center part of the said pressure reduction absorption panel, the movement of a pressure reduction absorption panel becomes better, and only the movable volume integral of this protrusion part has a pressure reduction absorption capacity. Therefore, even when the area of the vacuum absorption panel cannot be increased, the degree of vacuum can be further suppressed, and the vacuum absorption capacity necessary for preventing the deformation of the bottle-type container can be more efficiently secured. . Therefore, according to the invention which concerns on Claim 2, the small bottle type container which was excellent in heat resistance, and is hard to deform | transform can be provided.

  Since the invention according to claim 3 has a stepped shape from the side wall to the rising portion of the protruding portion along the circumference of the container, the movement of the vacuum absorbing panel is further improved. Since the vacuum absorption capacity increases by the movable body integral of the part, even if the area of the vacuum absorption panel cannot be increased, the vacuum absorption capacity required to further reduce the degree of vacuum and to prevent deformation of the bottle-type container Can be secured more efficiently. Therefore, according to the invention which concerns on Claim 3, the small bottle type container which was further excellent in heat resistance, and is hard to deform | transform can be provided.

  FIG. 1 is a front view showing the synthetic resin bottle-type container of the present invention in the form of a so-called 350 ml PET bottle 100 made of polyethylene terephthalate (PET) having an inner volume of 350 ml (milliliter), and FIG. ), (B) are a top view of the PET bottle 100 indicated by an arrow D1, and a bottom view indicated by an arrow D2, respectively.

  As shown in FIGS. 1 and 2, the PET bottle 100 is a so-called round bottle in which the mouth part 110 is connected to the body part 130 via the shoulder part 120 along the bottle central axis O1, and the body part 130 has a cylindrical shape. The shoulder 120 and the trunk 130 are connected to each other via an annular groove 150 dropped into the trunk 130 along the circumference of the trunk. In addition, the trunk portion 130 is connected to a bottom portion 140 that is a ground contact surface via an annular groove portion 160 that is dropped into the trunk portion 130 along the circumference of the trunk portion. Further, as shown in FIG. 1, the body portion 130 is connected to the first body portion 131 having the outermost diameter of the body portion 130 and the first body portion 131, and is dropped from the first body portion 131 into the body portion 130. The second body portion 132 is inserted.

  Since the PET bottle 100 of this embodiment is used as a heat-resistant bottle that can be filled with high-temperature contents, as shown in FIG. 2B, a plurality of (six in this embodiment) are provided along the periphery of the trunk portion 130. The vacuum absorption panel 170 is provided.

  3A to 3C are an enlarged view of a main part showing the reduced pressure absorption panel 170, an AA sectional view and a BB sectional view of FIG. 1, respectively.

  The PET bottle 100 includes a plane including the bottle center axis O1 and the bottle radial direction axis O2, that is, the bottle center axis O1, as shown in FIGS. 2B, 3B, and 3C. A side wall 180 is provided that drops vertically into the inside of the body part 130 toward the longitudinal section F and connects between the end part 170e of the reduced pressure absorption panel 170 and the first and second body parts 131 and 132. For this reason, the side wall 180 of this embodiment is positioned at right angles to the first and second body portions 131 and 132. In this case, the movement of the reduced pressure absorption panel 170 is improved, and the reduced pressure absorption capability is increased by the movable body integral of the side wall 180. Therefore, even when the area of the reduced pressure absorption panel 170 cannot be increased, the degree of reduced pressure can be suppressed and the PET. The vacuum absorption capacity necessary for preventing the deformation of the bottle 100 can be efficiently ensured. Therefore, according to such a configuration, it is possible to provide a small PET bottle that has excellent heat resistance and is difficult to deform.

  By the way, as shown in FIG. 3, the reduced pressure absorption panel 170 of the present embodiment includes an edge 171 that is inclined inward from the end 170 e connected to the side wall 180 and falls into the body 130, and the reduced pressure absorption panel connected to the edge 171. An annular bottom surface 171 a is formed between the end edge 171 of the reduced pressure absorption panel 170 and the rising portion 172 e of the projecting portion 172.

  As shown in FIGS. 3B and 3C, the protrusion 172 has a trapezoidal shape having a top surface 173 at the center of the reduced pressure absorption panel 170, and the top surface 173 constitutes a flat surface. In this case, the movement of the reduced pressure absorption panel 170 is improved, and the reduced pressure absorption capacity is increased by the movable body integral of the protrusion 172. Therefore, even when the area of the reduced pressure absorption panel 170 cannot be increased, the degree of reduced pressure can be further suppressed. In addition, the vacuum absorption capacity necessary to prevent deformation of the PET bottle 100 can be more efficiently ensured. Therefore, according to such a configuration, it is possible to provide a small PET bottle that is more excellent in heat resistance and hardly deformed.

  In this embodiment, as shown in FIGS. 3 (a) and 3 (c), it is flat along the bottle center axis O1 from the side wall 180 to the rising portion 172e of the protruding portion 172 along the circumference of the PET bottle 100. Is formed in a stepped shape from the side wall 180 to the rising portion 172e of the protruding portion 172. In this case, the movement of the reduced pressure absorption panel 170 is further improved, and the reduced pressure absorption capacity is increased by the movable body integral of the stepped shape portion made of the stepped portion 175. In addition, the degree of vacuum absorption capacity necessary for preventing deformation of the PET bottle 100 can be more efficiently secured. Therefore, according to such a configuration, it is possible to provide a small PET bottle that is further excellent in heat resistance and hardly deforms. In the present embodiment, the step portion 175 is one step, but there may be a plurality of steps, and the appearance shape is not limited to a step due to a flat surface, but may be a step due to a curved surface.

  Next, in order to clarify the difference between the synthetic resin bottle container of the present invention and the conventional synthetic resin bottle container, a conventional PET bottle 200 is illustrated in FIGS. 4 is a front view of a conventional PET bottle 200, and FIGS. 5A to 5C are enlarged views of main parts showing a conventional vacuum absorbing panel 270, respectively, and AA in FIG. It is sectional drawing and BB sectional drawing.

  The PET bottle 200 is a so-called 350 ml round bottle having a cylindrical body part 230 connected to the mouth part 210 and the shoulder part 220. Of the first and second body parts 231, 232, the second body part 232 includes: A plurality of vacuum absorbing panels 270 are provided along the periphery of the trunk. The reduced pressure absorption panel 270 includes an end 271 that is inclined and dropped into the body 230 from the end 270e connected to the second body 232, and a bottle center at the center of the reduced pressure absorption panel 270 connected to the end 271. It consists of a panel surface 272 having a recess 270n extending along the axis O1.

Hereinafter, the 350 ml PET bottle 100 according to the present invention of FIG. 1 is referred to as Example 1, and the conventional 350 ml PET bottle 200 of FIG. 4 is referred to as Comparative Example 1, and the degree of vacuum and the vacuum absorption capacity of these Example 1 and Comparative Example 1 are compared. The experimental data table is shown below. “Decompression degree” mmHg (millimeter of mercury) and “absorption capacity” ml (milliliter) shown in the following experimental data table indicate the results of measurement by the following test methods.
<Test method>
(1) Fill the measuring bottle with water. In addition, the bottle to be used should use what passed 24 hours or more after production.
(2) Attach a burette with a rubber stopper to the mouth and read the burette liquid surface position.
(3) Operate the vacuum pump and depressurize with a digital manometer (or mercury manometer) at a speed of 3 mmHg / sec.
(4) When the bottle is deformed, read the value of the digital manometer and the burette liquid level position.
(5) The absorption difference is the difference between the values of the burette before and after the test.
Note that 1 mmHg corresponds to approximately 133 kPa (kilopascal).

  Referring to Table 1, in Example 1, the degree of decompression is lower than that in Comparative Example 1, while the absorption capacity is increased. That is, according to the PET bottle 100 according to the present invention, it is apparent that the performance as a heat-resistant bottle is improved as compared with the conventional one.

  The above description shows only one embodiment of the present invention, and various modifications can be made within the scope of the claims by those skilled in the art. For example, the number of vacuum absorption panels is at least one. The top surface of the protruding portion is not limited to a flat surface, and may be a curved surface. The bottle is not limited to a round bottle, but may be a so-called square bottle in which the body of the container is formed in a square tube shape. The synthetic resin for molding the bottle is not limited to PET resin, but polyethylene naphthalate resin. Or a synthetic resin such as amorphous polyester. In addition, the layer structure is not limited to the single layer structure of the above resin, and a layer structure or regeneration in which a barrier resin such as EVOH, polyamide (especially xylylene group-containing polyamide) or cyclic polyolefin is blended or positioned in the middle of one or more layers. Layer structure in which the material layer is located in the middle, and oxygen absorbing resin (for example, an inorganic acid containing a transition metal catalyst (for example, Co, Fe, Mn, Ni, Ti) in a matrix of aliphatic nylon and aromatic nylon) It is also possible to adopt a layer structure in which one or more layers of oxygen absorbing resin or the like generally used in the form of a salt or a complex salt of an organic acid salt are located in the middle.

It is a front view which shows the PET bottle which is one form of this invention. (A), (b) is the top view and bottom view which respectively show the PET bottle of the same form. (A)-(c) is the principal part enlarged view which shows the decompression absorption panel of the same form, respectively, AA sectional drawing of FIG. 1, and BB sectional drawing. It is a front view which illustrates the conventional PET bottle. (A)-(c) is the principal part enlarged view which shows the decompression absorption panel of the example, respectively, AA sectional drawing of FIG. 4, and BB sectional drawing.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 PET bottle 110 mouth part 120 shoulder part 130 trunk | drum 131 1st trunk | drum 132 2nd trunk | drum 140 bottom 150,160 annular groove part 170 decompression absorption panel 170e decompression absorption panel edge 171 decompression absorption panel edge 171a decompression absorption panel Bottom surface 172 Depressurization absorbing panel projection 172e Projection rising portion 173 Projection top surface 175 Stepped portion 180 Side wall F Plane including bottle central axis and bottle radial axis O1 Bottle central axis O2 Bottle radial axis

Claims (3)

In a synthetic resin bottle type container equipped with a vacuum absorption panel in the body of the container,
A side wall that connects the end portion of the reduced pressure absorption panel and the body portion by dropping the decompression absorption panel vertically into the inside of the body portion toward a plane including the bottle central axis and the bottle radial axis; Characteristic synthetic resin bottle type container. The synthetic resin bottle-type container according to claim 1, further comprising a protruding portion having a flat top surface at a central portion of the vacuum absorbing panel. The synthetic resin bottle-shaped container according to claim 2, wherein a stepped shape is formed between the side wall and the rising portion of the protrusion along the circumference of the container.

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