JP2008030814A - Synthetic resin bottle body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pressure reducing-absorbing panel which has a large pressure reducing-absorbing capacity, and performs a smooth pressure reducing-absorbing motion with a good appearance by obtaining a smooth and uniform reverse curved deformation of the pressure reducing-absorbing panel. <P>SOLUTION: Panel walls 7 of the vertically long pressure reducing-absorbing panels 5 which is recessed in the body section 4 is constituted of one curved and swollen protruding wall section, the other curved and sunk recessed wall section, and a boundary wall section of a tilted wall structure which connects the recessed wall section with the protruding wall section. Then, large absorbing capacity is obtained by the reverse curved deformation of a combination of the protruding wall section and the boundary wall section. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a synthetic resin casing represented by a synthetic resin biaxially stretched blow-molded casing in which a vacuum absorbing panel is recessed in a body portion.

  Synthetic resin casings typified by polyethylene terephthalate biaxially stretched blow-molded casings are widely used as liquid storage containers, but the contents of the contents are sealed and stored in the body of the synthetic resin casing. Thereafter, a vacuum absorbing panel for absorbing the vacuum generated inside is depressed.

  That is, for example, as shown in FIG. 6, a plurality of (six in the illustrated example) decompression absorption panels 22 are arranged in the circumferential direction with the structure in which the column wall 25 remains in the body portion 21 of the housing 20. As shown in FIG. 7, each decompression absorption panel 22 is constituted by a depressed peripheral wall 23 and a panel wall 24 forming a bottom surface.

  The decompression absorption operation in the decompression absorption panel 22 shown in FIGS. 6 and 7 absorbs the decompression generated in the housing 20 by the panel wall 24 being bent and deformed into the posture shown by the broken line in FIG. It is supposed to be.

  In this decompression absorption operation, the flat panel wall 25 is merely bent and deformed in accordance with the decompression generated in the housing 20, so that a sufficiently large decompression absorption amount cannot always be obtained. In the case of a small body (approximately 500 ml or less), it has been difficult to sufficiently absorb the reduced pressure generated inside after filling and sealing the content liquid.

  That is, in the case of a small synthetic resin casing, the size of the reduced pressure absorption panel, which is a functional part that absorbs reduced pressure, is insufficient with respect to the reduced pressure generated inside, and sufficient vacuum absorption capacity can be secured. There is dissatisfaction that it is difficult.

As a prior art for solving this dissatisfaction, vertical ribs are provided over almost the entire height range on the left and right side end portions of the flat bottom wall portion which is the main part of the depressed vacuum absorbing panel, and the pair of left and right There is a type in which the wall portion between the vertical ribs is formed by molding a wall surface curved outward.
JP 2002-326618 A

  In the above-described prior art, when the decompression in the housing increases, the outwardly curved wall surface is inverted and deformed with the vertical ribs on both sides as fulcrums, thereby exhibiting a large decompression absorption capability. It has the advantage of being able to.

  However, in the above prior art, the reverse bending deformation of the wall surface is performed starting from the longitudinal ribs on both sides, but the reverse bending deformation operation on both sides of the wall surface acts in a direction that inhibits the movement of each other. However, until the decompression in the housing becomes sufficiently large, there is a problem that the inversion curved deformation of the wall surface does not occur, so that a smooth decompression absorption operation cannot be obtained.

  In addition, as described above, the reverse bending deformation operation on both sides of the wall surface acts in the direction in which the movements interfere with each other, so that the deformation form is not uniform and constant, and thus the appearance of the housing before opening There was a problem that the appearance deteriorated.

  Therefore, the present invention was devised to solve the above-described problems in the prior art, and it is a technical problem to obtain a smooth and uniform reversal curve deformation of the vacuum absorption panel. An object of the present invention is to provide a reduced pressure absorption panel that performs a reduced pressure absorption operation that is smooth and has a good appearance.

  The synthetic resin casing of the present invention is a vertically long vacuum absorption panel composed of a depressed peripheral wall and a panel wall which is a bottom wall, and is depressed in the trunk portion. The panel wall of the vacuum absorption panel is From one of the left and right convex wall portions bulging gently curved, the other concave wall portion gently curved and depressed, and the boundary wall portion of the inclined wall structure connecting the concave wall portion and the convex wall portion It is configured.

  That is, the panel wall constituting the main part of the vacuum absorbing panel is divided into a convex wall portion that is curved and bulged and a concave wall portion that is curved and depressed, and the space between the convex wall portion and the concave wall portion is divided. , And connected by a boundary wall portion of an inclined wall structure forming a step.

  In this way, the panel wall of the decompression absorption panel bulges one of the left and right convex wall portions, and conversely concavates the other left and right concave wall portions. Therefore, when decompression occurs in the housing, the panel wall In other words, the other recessed wall portion already in the depressed posture causes the depressed deformation for absorbing the reduced pressure very smoothly.

  When the concave wall is deformed by depression, the concave deformation of the concave wall starts as a starting point, and the convex wall also smoothly sinks and deforms while being guided to the concave wall, and performs a reduced pressure absorption operation. Since the depression deformation of the part becomes an inverted bending deformation, a large decompression absorption capability is exhibited.

  Since the depression deformation of the convex wall portion is a reverse bending deformation, a tensile force is applied to the adjacent portion. However, since the tensile force is absorbed by the concave curvature deformation of the concave wall portion, the convex wall It is possible to obtain a smooth depression deformation of the entire panel wall without acting in the direction of inhibiting the reverse bending deformation of the part.

  Furthermore, since only one convex wall portion is provided in the reduced pressure absorption panel, the inverted curved deformation form for absorbing the reduced pressure is not compared with other convex wall portions. The reverse curved deformation form of the part does not become a problem in the appearance of the housing.

  In another configuration of the present invention, the upper and lower ends of the boundary wall are positioned on a virtual center axis that bisects the vacuum absorption panel to the left and right, and the central portion of the boundary wall is biased toward the concave wall. Thus, the entire boundary wall is configured in a curved posture.

  In the case where the central part of the boundary wall part is biased toward the concave wall part side, the convex wall part can be formed larger than the concave wall part in the panel wall of the vacuum absorbing panel. Since the central portion of the convex wall portion is biased toward the portion side, the lateral width at the central portion of the convex wall portion is larger than that of the other portions.

  Another configuration of the present invention is such that the inclination angle of the boundary wall portion with respect to a virtual bottom plane connecting the recessed ends of the recessed peripheral walls is set to 35 ° or less.

  When the inclination angle of the boundary wall is set to 35 ° or less, the acting force of the boundary wall functioning as a reinforcing rib against the pressure acting on the boundary wall panel wall is greatly suppressed. become.

  Another configuration of the present invention is a configuration in which the concave wall portion of the panel wall is depressed and inclined toward the lower boundary corner portion that is a connecting portion with the boundary wall portion.

  In the case where the concave wall portion of the panel wall is recessed and inclined toward the lower boundary corner portion, the concave wall portion adjacent to the lower boundary corner portion, that is, the concave portion adjacent to the convex wall portion via the boundary wall portion. Since the wall part forms the most depressed part of the concave wall part, the concave part is displaced at the earliest time when the concave wall part is deformed.

  Further, another configuration of the present invention is such that the degree of curved bulging of the convex wall portion of the panel wall is such that the bulging end of the convex wall portion does not protrude outward from both side edges of the vacuum absorbing panel. Is.

  In the case where the degree of bulging of the convex wall portion is such that it does not protrude outward from both side edges of the reduced pressure absorption panel, the reduced pressure absorption panel should form a protruding portion on the housing body when the container is opened. This prevents the attached label from protruding outward.

  In another configuration of the present invention, a plurality of vacuum absorbing panels are arranged in parallel at equal intervals along the circumferential direction in a cylindrical body.

  In the case where a plurality of reduced pressure absorption panels are arranged in parallel on the cylindrical body, the reduced pressure absorption deformation appears uniformly over the entire circumference of the cylindrical body, and the reduced pressure is reduced. The reinforcing rib effect due to the provision of the absorption panel will appear evenly.

Since the present invention has the above-described configuration, the following effects can be obtained.
In the synthetic resin casing of the present invention, the panel wall constituting the main part of the vacuum absorbing panel causes the left and right convex wall portions to bulge, and conversely the left and right other concave wall portions are depressed. Therefore, the concave wall portion causes the concave deformation very smoothly, and the convex wall portion smoothly sinks and deforms starting from the concave deformation of the concave wall portion, so that an extremely smooth decompression absorption operation can be obtained.

  In addition, the tensile force generated when the convex wall portion undergoes curve reversal deformation is absorbed by the concave wall portion, so that it does not act in the direction of hindering the reverse curve deformation of the convex wall portion, thereby causing a large pressure reduction. Absorption capacity will be exerted reliably without difficulty.

  Furthermore, since only one convex wall portion that is reversely curved and deformed is provided in the reduced pressure absorption panel, the reverse curved deformation is independently performed in the reduced pressure absorption panel. This non-uniformity does not become a problem, and the reduced pressure absorption operation does not deteriorate the appearance of the casing.

  In the case where the central part of the boundary wall part is biased toward the concave wall part side, the convex wall part can be enlarged, and the width of the central part of the convex wall part can be increased, so that the absorption is large. Capacitance can be obtained, and reversal curve deformation of the convex wall portion can be made smooth without difficulty.

  When the inclination angle of the boundary wall is set to 35 ° or less, the acting force of the boundary wall functioning as a reinforcing rib against the pressure acting on the boundary wall panel wall is greatly suppressed. Therefore, the reverse curved deformation of the convex wall portion can be caused smoothly.

  In the case where the concave wall portion of the panel wall is depressed and inclined toward the lower corner of the boundary, the portion of the concave wall portion that is depressed and displaced at the earliest time is positioned closest to the convex wall portion. Therefore, the depression displacement of the concave wall portion directly triggers the reverse bending deformation of the convex wall portion, and thereby an extremely smooth reverse bending deformation operation of the convex wall portion can be obtained.

  In the case where the degree of bulging of the convex wall portion is such that it does not protrude outward from both side edges of the reduced pressure absorption panel, the reduced pressure absorption panel does not form a protruding part in the housing body, so There is no fear of a sense of incongruity in gripping the housing, and the shrink label can be suitably attached and the attached state can be maintained well.

  In the case where a plurality of reduced pressure absorption panels are arranged in parallel on the cylindrical body, the reduced pressure absorption deformation appears uniformly over the entire circumference of the cylindrical body, and the reduced pressure is reduced. Since the reinforcing rib effect due to the provision of the absorption panel can be made to appear evenly, the appearance of the synthetic resin casing having the cylindrical body portion can be maintained at a good level.

  Embodiments of the present invention will be described below with reference to the drawings.

  1 to 4 show an embodiment of a synthetic resin casing 1 according to the present invention. At the lower end of a cylindrical mouth tube portion 2 provided with a thread, a stop ring and a neck ring on the outer peripheral surface. A cylindrical body portion 4 is continuously provided through a tapered cylindrical shoulder portion 3 whose diameter is expanded downward, and the bottom end of the body portion 4 is closed by a bottom portion 15.

  The body 4 is provided with a circumferential groove-shaped reinforcing circumferential rib 14 in the vicinity of the boundary with the shoulder 3 and in the vicinity of the boundary with the bottom 15, and an upper end and a lower end are provided between the upper and lower circumferential ribs 14. A plurality of (six in the case of the illustrated embodiment) reduced-pressure absorption panels 5 are arranged in parallel at equal intervals along the circumferential direction, with the column wall 13 remaining between them. Configured.

  Each reduced pressure absorption panel 5 includes a depressed peripheral wall 6 that positions the entire reduced pressure absorption panel 5 in a depressed shape with respect to the outer surface of the body 4, and a panel wall 7 that forms a bottom wall and forms a reduced pressure absorption functional part. It is composed of

  The panel wall 7 includes a convex wall portion 8 (see FIG. 3) that is gently curved and bulged on one of the left and right sides (right side in the case of the illustrated embodiment), and a concave wall portion 9 that is gently curved and depressed (see FIG. 3). 3), and a boundary wall portion 10 having an inclined wall structure that connects the convex wall portion 8 and the concave wall portion 9 to each other.

  The boundary wall portion 10 has its upper and lower ends positioned at a point where a virtual center axis m that divides the panel wall 7 into left and right and the peripheral edge of the panel wall 7 intersect with each other along the vertical direction. The center portion is biased toward the concave wall portion 9 (see FIG. 2), resulting in a curved posture.

  Further, the concave wall portion 9 is configured to be depressed and inclined toward the lower boundary corner portion 12 that is a connection portion with the boundary wall portion 10, and on the contrary, the convex wall portion 8 is connected to the boundary wall portion 10. Since it has the structure which bulged and inclined toward the boundary upper corner | angular part 11 which is a part, the boundary wall part 10 becomes a structure where a width | variety becomes large as it approaches a center part.

  Therefore, in the panel wall 7, the convex wall portion 8 has a larger surface area than the concave wall portion 9, and the convex wall portion 8 and the concave wall portion 9 are located at the center portion in the height direction. The step between them becomes the largest (see FIG. 3).

  And the boundary wall part 10 inclines (refer FIG. 4) with the inclination angle (alpha) of 35 degrees or less with respect to the bottom plane n which is a hypothetical | virtual plane which passes the lower end edge of the depression surrounding wall 6, thereby The reinforcing rib function of the wall portion 10 with respect to the panel wall 7 is greatly suppressed, and the inverted curved depression deformation of the combination of the convex wall portion 8 and the boundary wall portion 10 is caused without difficulty.

  Further, the degree of the curved bulging of the convex wall portion 8 is such that the bulging end of the convex wall portion 8 (which is the same as the central portion in the height direction of the upper boundary corner portion 11) It is the extent which does not come out outside the edge (refer to FIG. 3). As a result, a part of the reduced pressure absorption panel 5 protrudes outside, or the appearance appearance is deteriorated, or the shrink label is wound and assembled. Prevent inconveniences such as adverse effects.

  When decompression occurs in the housing 1 in a state where the content liquid is sealed and stored, first, the concave wall portion 9 of the panel wall 7 is depressed and deformed with the boundary lower corner portion 12 being most depressed and displaced. Starting from the depression displacement of the portion 12, the combination of the convex wall portion 8 and the boundary wall portion 10 undergoes reverse bending depression deformation while depression displacement, and exhibits a large absorption capacity.

  At this time, the combination of the convex wall portion 8 and the boundary wall portion 10 is inverted and deformed by using the upper boundary corner portion 11 as an inversion portion, and the tensile force generated during the inversion deformation is caused by the lower boundary corner portion 12. It is absorbed by the depression displacement movement.

  Therefore, the inverted depression deformation of the combination of the convex wall portion 8 and the boundary wall portion 10 is hardly hindered by the tension force and is smoothly performed.

  FIG. 5 shows a reduced pressure absorption characteristic curve a of the case 1 of the embodiment of the present invention shown in FIGS. 1 to 4 and a reduced pressure absorption characteristic curve b of the prior art case 20 shown in FIGS. It is clearly shown that the housing 1 of the present invention exhibits a large reduced pressure absorption capability with respect to the conventional housing 20.

1 is an overall front view of an embodiment of the present invention. FIG. 2 is an enlarged front view of the reduced pressure absorption panel shown in FIG. 1. FIG. 2 is an enlarged longitudinal sectional view taken along the line AA in FIG. These are the expanded plane sectional views which looked at the cutting arrow along the BB line in FIG. These are characteristic comparison graphs showing comparison of reduced pressure absorption characteristics. These are whole front views which show an example of the conventional housing. [Fig. 7] Fig. 7 is an enlarged plan sectional view taken along the line CC in Fig. 6 as viewed along a cutting arrow.

Explanation of symbols

1; Housing 2; Mouth tube portion 3; Shoulder portion 4; Body portion 5; Depressurized absorption panel 6; Depressed peripheral wall 7; Panel wall 8; Convex wall portion 9; Concave wall portion 10; Part 12; lower corner part 13; column wall 14; peripheral rib 15; bottom 20; housing 21; body part 22; decompression absorption panel 23; m; central axis n; bottom plane α; inclination angle

Claims (6)

  A vertically decompressed absorption panel that is recessed in the trunk portion is constituted by a recessed peripheral wall and a panel wall that is a bottom wall, and the panel wall is a convex wall portion that is gently curved and bulged on one of the left and right sides, The other is a synthetic resin casing made up of a concave wall portion that is gently curved and depressed, and a boundary wall portion having an inclined wall structure that connects the concave wall portion and the convex wall portion.   The upper and lower ends of the boundary wall portion are positioned on a virtual center axis that bisects the vacuum absorption panel to the left and right, and the central portion of the boundary wall portion is biased toward the concave wall portion, The synthetic resin casing according to claim 1, wherein the entire body is configured in a curved posture.   The synthetic resin casing according to claim 1 or 2, wherein an inclination angle of the boundary wall portion with respect to a virtual bottom plane connecting the depressed ends of the depressed peripheral walls is set to 35 ° or less.   The synthetic resin casing according to any one of claims 1 to 3, wherein the concave wall portion of the panel wall is configured to be depressed and inclined toward a lower boundary corner portion that is a connecting portion with the boundary wall portion.   The curved bulging degree of the convex wall portion of the panel wall is set such that the bulging end of the convex wall portion does not protrude outward from both side edges of the vacuum absorbing panel. Synthetic resin housing.   The synthetic resin casing according to any one of claims 1 to 5, wherein a plurality of reduced pressure absorption panels are arranged in parallel at equal intervals along a circumferential direction in a cylindrical body portion.

Images