JP5120976B2 - Oval bottle - Google Patents

Description

  The present invention relates to a glass or synthetic resin bottle having an elliptical planar shape on the outer periphery of a body portion.

For example, as shown in the following Patent Document 1, a bottle is known in which the planar shape of the outer periphery of the body is an elliptical shape.
The peripheral shape of such a conventional elliptical bottle is not exactly a geometrical ellipse, but is a combination of two or three arcs of different radii.
For example, the “conventional ellipse” shown in the upper part of FIG. 6 has a shape that approximates the geometric ellipse shown in the lower part of the figure, but actually an arc having a radius R = 15.83 mm and an arc having a radius R = 42 mm are used. It is a combination. Therefore, at the boundary between these arcs, the radius of curvature changes stepwise from 15.83 mm to 42 mm.

JP 59-84772 A

As shown in FIG. 15, the conventional elliptical bottle has a problem that bottle arrangement is easily disturbed on the transport line and bottle clogging is likely to occur.
Moreover, as a packaging form of the bottle, there is a bulk packaging in which a large number of bottles are aligned and packed in a matrix state. Bulk packaging does not use a box such as corrugated cardboard as a packaging material, so there is little packaging material and the volume of the package is minimized. Conventional oval bottles are likely to be disturbed when aligned, making it difficult to perform bulk packaging.

  It is an object of the present invention to develop an elliptical bottle that reduces disturbance of the bottle arrangement on the conveyance line, improves bottle clogging, and enables bulk packaging.

In the present invention, the horizontal cross-section outer peripheral shape in the maximum diameter portion is substantially,
(X / A) ⁿ + (y / B) ⁿ = 1
However, n is 2.15 to 3, and A and B are oval-shaped bottles characterized in that they are positive real curves.

This curve is called a super ellipse.
n is suitably 2.15-3, and if it is less than 2.15, the bottle arrangement is greatly disturbed on the conveying line and the collision strength is also reduced. If it exceeds 3, it will be closer to a rectangular image rather than an elliptical shape.
A: B is suitably about (1.1-3): 1. If the AB ratio is less than 1.1, a circular image is formed rather than an ellipse, and if it exceeds 3, it is too flat and inappropriate as a bottle.

The above equation of the curve is geometrical, but when a bottle is actually formed, a shape distortion or the like always occurs due to a slight manufacturing error. Therefore, in the present invention, the horizontal cross-sectional outer peripheral shape in the bottle maximum diameter portion may be “substantially” a curve of the above formula.
Since the error of the diameter after manufacturing a bottle such as a glass bottle is within about ± 1%, the term “substantially” here means that an error within ± 1% is allowed. Specifically, as shown in FIG. 19, an enlarged shape p (dashed line) enlarged 1% outside the geometrically accurate design curve A (solid line) of the above equation, and a reduced shape q reduced 1% inside. When a (broken line) is drawn and the shape falls between the enlarged shape p and the reduced shape q, it is assumed that the curve is substantially the above equation.

The elliptical bottle of the present invention is less disturbed in the arrangement of bottles on the transport line, and the possibility of clogging is reduced. In addition, since the bottle arrangement is less disturbed when the bottles are aligned, bulk packaging is also possible.
Furthermore, since the radius of curvature of the maximum diameter portion continuously changes over the entire circumference, the design is excellent, and the impact strength when the bottles collide with each other is improved.

It is a front view of the glass bottle of an Example. It is a top view of the glass bottle of an Example. It is explanatory drawing of a super ellipse. It is explanatory drawing of the shape change of a super ellipse when n changes. It is explanatory drawing of the curvature radius of a super ellipse when n changes. It is a comparison figure of the super ellipse of n = 2 and the conventional ellipse shape approximated to this. It is a comparison figure of the super ellipse of n = 2.25 and the conventional ellipse shape approximated to this. It is a comparison figure of the super ellipse of n = 2.5 and the conventional ellipse shape approximated to this. It is a comparison figure of the conventional ellipse shape approximated with the super ellipse of n = 3. It is a comparison figure of the super ellipse of n = 4 and the conventional ellipse shape approximated to this. It is explanatory drawing of the relationship between the load width when a bottle collides, and an impact strength ratio. It is explanatory drawing of the long diameter side contact width of a super ellipse and the conventional ellipse. It is explanatory drawing of the short diameter side contact width of a super ellipse and the conventional ellipse. It is explanatory drawing of the long diameter side and short diameter side contact width of a super ellipse and a conventional ellipse, and a collision strength improvement rate. It is explanatory drawing of disturbance of the bottle arrangement | sequence on a conveyance line. It is explanatory drawing of the space | interval with an adjacent bottle. It is explanatory drawing of the space | interval with an adjacent bottle. It is a comparison figure of the major axis end curvature radius of a super ellipse and a conventional ellipse. It is explanatory drawing of a substantial super ellipse.

FIG. 1 is a front view of a glass bottle 1 of the embodiment, and FIG. 2 is a plan view.
The bottle 1 includes a mouth part 2, a shoulder part 3, a body part 4, a skirt part 5, and a bottom part 6.
The body part 4 is a straight body made of a vertical curved surface, and the entire body part is the maximum diameter part of the bottle. As shown in FIG. 2, the planar shape of the body portion 4 is an ellipse, and its outer peripheral curve is substantially
(X / 32.5) ^2.6 + (y / 26.25) ^2.6 = 1
It has become a super ellipse.
This equation is a case where the center of the bottle is the origin and the x axis is taken in the major axis direction and the y axis is taken in the minor axis direction, and the unit is mm.

The shoulder portion 3 has a tapered surface shape with a diameter decreasing upward from the upper end of the trunk portion toward the mouth portion, and becomes a curved surface that gradually changes from a super ellipse of the trunk portion to a circular shape of the mouth portion as it goes upward. Yes.
The mouth portion 2 has a cylindrical shape, a thread is formed on the outer peripheral portion, and a bead is formed below the thread.
The skirt part 5 has a tapered surface shape whose diameter decreases from the lower end of the body part 4 toward the bottom part 6.

  When the bottle 1 of the example was conveyed by the conveyance line at the time of molding and filling, the bottle arrangement was less disturbed and troubles such as bottle clogging did not occur. In addition, there was little disturbance in the bottle arrangement during bulk packaging, and bulk packaging was possible without problems.

[Super ellipse]
3-5 is explanatory drawing of a super ellipse.
Super ellipse
(X / A) ⁿ + (y / B) ⁿ = 1
The diameter of the x-axis is 2A and the diameter of the y-axis is 2B. As shown in FIGS. When n = 2, it is a normal ellipse.
3 to 5 are cases where A = 30 mm and B = 20 mm.
The feature of the super ellipse is that the radius of curvature changes continuously and smoothly over the entire circumference, as shown in FIG.

[Comparison of Super Ellipse and Conventional Ellipse]
The outer peripheral shape of a conventional elliptical bottle is precisely a combination of two or three arcs of different radii. Hereinafter, such an elliptical shape is referred to as a “conventional ellipse”.
6 to 10 compare the super ellipse when n is 2 to 4 and the conventional ellipse approximated thereto. In both cases, the major axis (diameter) is 60 mm and the minor axis (diameter) is 40 mm.

FIG. 6 shows a super ellipse (normal ellipse) with n = 2 and a conventional ellipse that approximates this.
The conventional ellipse is a combination of arcs having a radius of 15.83 mm and a radius of 42 mm. Therefore, at the boundary between these arcs, the radius of curvature changes stepwise (abruptly) from 15.83 mm to 42 mm.
On the other hand, as shown in FIG. 5, the radius of curvature of the super ellipse changes continuously and smoothly over the entire circumference.

FIG. 7 shows a super ellipse of n = 2.25 and a conventional ellipse approximated thereto.
A conventional ellipse is a combination of circular arcs having a radius of 17.5 mm and 50 mm. Therefore, at the boundary between these arcs, the radius of curvature changes stepwise (abruptly) from 17.5 mm to 50 mm.
On the other hand, as shown in FIG. 5, the radius of curvature of the super ellipse changes continuously and smoothly over the entire circumference.

FIG. 8 shows a super ellipse of n = 2.5 and a conventional ellipse approximated thereto.
A conventional ellipse is a combination of arcs with radii of 30 mm, 17 mm and 80 mm. Accordingly, at the boundary between these arcs, the radius of curvature changes stepwise (rapidly) from 30 mm to 17 mm and from 17 mm to 80 mm.
On the other hand, as shown in FIG. 5, the radius of curvature of the super ellipse changes continuously and smoothly over the entire circumference.

FIG. 9 shows a super ellipse of n = 3.0 and a conventional ellipse approximated thereto.
A conventional ellipse is a combination of arcs with radii of 50 mm, 15 mm and 140 mm. Therefore, at the boundary between these arcs, the radius of curvature changes stepwise (rapidly) from 50 mm to 15 mm and from 15 mm to 140 mm.
On the other hand, as shown in FIG. 5, the radius of curvature of the super ellipse changes continuously and smoothly over the entire circumference.

FIG. 10 shows a super ellipse with n = 4.0 and a conventional ellipse approximating it.
A conventional ellipse is a combination of arcs with radii of 150 mm, 12 mm and 300 mm. Therefore, at the boundary between these arcs, the radius of curvature changes stepwise (rapidly) from 150 mm to 12 mm and from 12 mm to 300 mm.
On the other hand, as shown in FIG. 5, the radius of curvature of the super ellipse changes continuously and smoothly over the entire circumference.

[Impact strength]
When a glass bottle collides, the impact strength of the bottle is related to the width (contact width) where the bottles deform and contact when colliding.
In FIG. 11, the horizontal axis represents the contact width, the vertical axis represents the impact strength ratio, and the impact strength is 1 when the contact width is 1 mm.
As shown in the figure, the impact strength increases as the contact width increases.

12 and 13 compare the contact widths of the super ellipse shown in FIGS. 6 to 10 and the conventional ellipse. FIG. 12 shows the major axis side, and FIG. 13 shows the minor axis side. In the figure, “SP ellipse” means a super ellipse. Both are contact widths when the deformation amount when the bottle collides is 0.03 mm.
Even in the conventional ellipse, the contact width increases as the radius of curvature increases. In the super ellipse, the contact width increases as the index n increases, but the increase (line slope) is considerably larger than in the conventional ellipse.

FIG. 14 summarizes the contact width and impact strength improvement rate of the super ellipse and the conventional ellipse shown in FIGS. 6 to 10, and in FIG. 14, “shape 1” to “shape 5” mean the cases of FIGS. To do. The impact strength improvement rate is expressed in% for each super ellipse with different n, where 1 is a normal ellipse with n = 2.0.
When the index n of the super ellipse is less than 2, the contact width of the conventional ellipse becomes wide. If it is 2 or more, the contact width of the super ellipse becomes large, and the impact strength is improved although it is several percent. As a result, it can be seen that when n is larger than 2.25, the super ellipse is superior to the conventional ellipse.

[Bottle alignment is difficult]
FIG. 15 shows a state where the elliptical bottles are being conveyed while in contact with the conveyance line, and the arrangement of the bottles is disturbed. When the bottles are aligned during bulk packaging, the elliptical bottles are similarly disturbed.
Such disturbance of the bottle arrangement is related to a gap between adjacent bottles at a predetermined distance from the center of the bottle as shown in FIGS. That is, the smaller the gap, the less likely the bottle arrangement is disturbed. FIG. 16 shows a super ellipse with n = 2 and n = 2.25 and a conventional ellipse that approximates it (in the case of FIGS. 6 and 7). FIG. 17 shows a super ellipse with n = 2.5 and n = 3. Is a conventional ellipse approximating to (in the case of FIGS. 8 and 9).
When n = 2, the super ellipse has a larger gap than the conventional ellipse, and the bottle arrangement is more disturbed than the conventional ellipse. However, when n is 2.25 or more, the gap is smaller than the conventional ellipse, and the bottle arrangement. Is less disturbed than the conventional ellipse. As a result, it is found that when n is 2.25 or more, the bottle arrangement is less likely to be disturbed than the conventional ellipse, bottle clogging on the conveyance line can be prevented, and it is advantageous for bulk packaging.

[Lower limit of n]
FIG. 18 shows a comparison of the radius of curvature of the major ellipse between the super ellipse and the conventional ellipse. The solid line is the super ellipse and the broken line is the conventional ellipse. Both the impact strength and the difficulty of disturbance of the bottle arrangement are derived from the radius of curvature on the longer diameter side, and the larger the radius of curvature, the more advantageous. As shown in FIG. 18, when the index n of the super ellipse is 2.15 or more, the radius of curvature of the super ellipse becomes sufficiently larger than that of the conventional ellipse, and the superiority becomes clear. Therefore, the lower limit value of n in the present invention is set to 2.15.

1 bottle 2 mouth 3 shoulder 4 body 5 hem 6 bottom 7 transport line

Claims (1)

The horizontal cross-sectional outer periphery shape at the maximum diameter part is substantially
(X / A) ⁿ + (y / B) ⁿ = 1
However, an elliptical bottle characterized in that n is 2.15 to 3 and A and B are positive real curves.

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