Patent Grant
8215509
The invention relates to plastic bottles suitable for storing and dispensing contents having a comparatively high viscosity, for example, a jelly beverage.
Generally, plastic bottles, for example, PET bottles, store products having comparatively low viscosities, for example, water, tea, carbonated beverages, juices, and the like. Bottles containing those low viscous fluids have been widely marketed and have been sold at retail stores and in automatic vending machines. However, plastic bottles containing products having comparatively high viscosities such as jelly beverages, which are squeezed to be dispensed for drinking, have not been marketed.
Plastic bottles that can be folded up after use for waste recovery and plastic bottles whose volume before filling can be temporarily reduced for efficient stacking and shipping have been available. For example, a plastic bottle can be formed with soft walls and rigid walls, alternating in the circumferential direction, so that sections of the shoulder, body, and base having soft walls would fold inward after use. (See Japanese Kokai Publications Hei-8-24474 and Hei-10-230919.)
Another container known as a spout-pouch container is suitable for containing a jelly beverage. For example, one spout pouch container has a bag-like container main unit having a flexible sheet that has a spout of rigid resin heat sealed thereto. (See Japanese Kokai Publication Hei-2004-29970.) In use, the consumer pushes the flexible sheet to squeeze out the jelly beverage from the spout. In addition, the spout pouch container has been designed so as to stand erect in cooler cases found in stores. (See Japanese Kokai Publication Hei-2006-219157.)
The sale of spout pouch containers, however, has been limited to in-store sales, and they have not been sold in automatic vending machines (hereinafter “vending machines”). Indeed, vending machines are designed to hold aluminum cans or rigid plastic bottles that are strong enough to withstand horizontal placement. In contrast, the main unit of the spout pouch container would droop if stacked in vending machines.
The insertion of spout pouch containers in aluminum or rigid plastic tubes in order to hold spout pouch containers in vending machines has been considered. Such a method, however, has poor operational efficiency and is costly.
In addition, the use of plastic bottles to store comparatively high viscous products like jelly beverages and for vending in vending machines has been considered but has been limited by the bottle configuration. If the bottle is too strong, it is difficult, if not impossible, to dispense the jelly beverage. Conversely, if the bottle strength is reduced to allow a jelly beverage to be dispensed by squeezing, the strength becomes insufficient for stacking in vending machines, and it becomes difficult to open the cap.
Accordingly, there remains a need to provide a plastic bottle that is suitable for vending by vending machines and for storing and dispensing products having comparatively high viscosities.
A bottle is provided with a mouth, a flexible main unit having a tubular body section and in fluid communication with the mouth, a base forming a bottom of the main unit and configured to support the bottle to stand upright, and a rigid portion located above the main unit and having greater traverse strength than the main unit. The mouth, main unit, and base define a retention space with a central axis. The rigid portion includes regions facing each other across from the central axis at the most distant position from the central axis. Moreover, the tubular body section of the main unit deforms into a substantially flat shape when an external force is applied in a transverse direction without the rigid portion undergoing plastic deformation. In one aspect, the tubular body section is a cylindrical body section.
It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.
Disclosed herein are plastic bottles suitable for dispensing by vending machines. Moreover, the plastic bottles are configured to contain and dispense a product such as a viscous food or beverage.
In an embodiment disclosed herein, a bottle is provided with a mouth, a flexible main unit having a tubular body section and in fluid communication with the mouth, a base forming a bottom of the main unit and configured to support the bottle to stand upright, and a rigid portion located above the main unit and having greater traverse strength than the main unit. The mouth, main unit, and base define a retention space with a central axis. The rigid portion includes regions facing each other across from the central axis at the most distant position from the central axis. Moreover, the tubular body section of the main unit deforms into a substantially flat shape when an external force is applied in a transverse direction without the rigid portion undergoing plastic deformation.
In one embodiment, the plastic bottle is manufactured from a thermoplastic resin using various molding techniques. Suitable resins include at least one of polyethylene terephthalate (PET), polyethylene, and polypropylene. Prior to molding, the resin can be strengthened by biaxial stretching.
The mouth, main unit, base, and rigid portion can be integrally molded from a resin. The rigid portion and the main unit can be easily formed as a single molded article from the same resin. Suitable molding techniques include blow molding, injection blow molding, and two-axis stretch blow molding. For example, when the plastic bottle is formed using the injection stretch blow molding technique, the molding steps include injection molding of a preform into a predetermined shape, and stretching of the preform in the longitudinal direction by a stretching rod and in the transverse direction by air blowing.
Following molding and/or before filling the plastic bottle with a product, the plastic bottle can be washed and/or sterilized, for example, by heated water or chlorine sterilization techniques. After the plastic bottle is filled with the product, the mouth may be closed. In one embodiment, the mouth and a cap are sealed, providing a bottle in a sealed state. In one embodiment, the rigid portion is configured to allow the bottle to be pressed in a downward direction such that the cap opens.
The retention space defined by the main unit, mouth, and base can contain a comparatively high viscous product. Exemplary products for use with the plastic bottles disclosed herein include, without limitation, jelly beverages, liquid foods, miso, mayonnaise, and jams. Use of the plastic bottles disclosed herein is not restricted to comparatively high viscous products, however. The plastic bottles can alternatively contain comparatively low viscous products, for example, water, tea, fruit juices, alcohol, energy drinks, and carbonated beverages.
A consumer, food service provider, or machine may dispense the product from the plastic bottle by applying a transverse force, for example, squeezing, to the main unit. Depending on the amount of force applied, at least a portion of the product can be expelled through the mouth. Generally, a sufficient amount of force is slightly more than the force a consumer uses to hold a bottle in one hand. Specifically, the tubular body section of the main unit deforms to a flat or substantially flat shape by the application of force. Consequently, at least a portion of the product contained therein, even if exhibiting a comparatively high viscosity, can be expelled through the mouth.
Although the tubular body section deforms upon the application of a sufficient amount of force, the rigid portion is configured to maintain the traverse strength of the plastic bottle. Consequently, when plastic bottles, alone or in combination with other plastic bottles, are stacked horizontally, for example, during transit, in refrigerators or coolers, or in vending machines, the rigid portions support the plastic bottles such that deformation of the tubular body sections are inhibited. Furthermore, the bottles can be stored horizontally or at an angle between the horizontal and vertical planes in vending machines without deforming and without modifying the structure of existing vending machines.
Furthermore, the plastic bottles disclosed herein include at least two points of rigidity—the base and the rigid portion, the combination of which inhibits or reduces the incidence of deformation during shipment and storage.
Such strength of the bottles disclosed herein is useful for the consumer. For example, the rigid portion can be configured to provide sufficient resistance for removing a cap from the mouth. In an embodiment, the rigid portion is positioned proximate the mouth such that a cap can be opened with comparatively little twisting force.
In one aspect, the rigid portion includes a circumferential wall section. At least a portion of the circumferential wall section can contact the exterior of the upper wall of the main unit. For example, an inner wall of the circumferential wall section can make surface contact with an outer wall of an upper wall of the main unit. The force sustained by the circumferential wall section can be released toward the upper wall of the main unit. In particular, this structure is effective when the retention space is filled with a product proximate to the height of the upper wall.
Moreover, the rigid portion can include circumferential sections located at the most distant position from the central axis and facing with each other such that the central axis is interposed between them, and a connecting section above the upper wall of the main unit that connects the circumferential wall section with the mouth.
In one embodiment, the connecting section connects in strip shape with the mouth and at least two locations of the circumferential wall section. By using a strip shape, the connecting section connects the rigid portion to a portion of the upper wall rather than to the entire upper wall of the main unit. In so doing, the amount of materials and consequently, the costs associated with the connecting section can be reduced. Furthermore, since the connecting section connects with at least two locations of the circumferential wall section, the durability of the circumferential wall section relative to a transverse load can be enhanced in comparison to connection at only one location. In other embodiments, the connecting section connects with two locations, three locations, four locations, five locations, six locations or more of the circumferential wall section.
In one embodiment, the rigid portion can function as a discrete entity, independent of the main unit. As a consequence, deformation of the tubular body section to a substantially flat shape is not hindered. In another embodiment, the main unit includes a rigid portion, and the main unit is configured to deform in accordance with the embodiments disclosed herein.
In yet another embodiment, the connecting section can connect at least a part of the rigid portion to the main unit using at least two discontinuous sections. The circumferential wall section of the rigid portion can extend in the circumferential direction of the main unit such that it is discontinuous at two sections facing and enclosing the central axis. Four edges facing the discontinuous sections can be connected to the mouth by the connecting section. Use of discontinuous sections can reduce the amount of materials and consequently, the cost associated with contacting the rigid portion to the main unit in comparison to a ring-shaped connecting section.
In yet another embodiment, at least one concave rib extends in the elongate direction of the circumferential wall section. The traverse strength of the circumferential wall section is enhanced with the addition of at least one concave rib. In one embodiment, two or more concave ribs are distributed uniformly about the circumferential wall section. In another embodiment, two or more concave ribs are spaced apart at non-uniform distances.
In one aspect, the base can be more rigid than the main unit. Increasing the rigidity of the base relative to the main unit facilitates the ability of the plastic bottle to stand upright, which permits the plastic bottles disclosed herein to be stacked vertically in, for example, refrigerators or coolers.
In an embodiment, the main unit includes an upper body section extending upward from the tubular body section, a tapered shoulder connecting the upper body section with the mouth, and at least one step between the upper body section and the shoulder. The circumferential wall section of the rigid portion can be positioned at the at least one step, and the connecting section can be positioned at the shoulder. In an embodiment, the connecting section can connect the rigid portion to the main unit at the uppermost portion of the shoulder.
In a deformation configuration, that is, when the tubular body section deforms to a substantially flat shape, the inner wall of the upper body section can contact the inner wall of the shoulder. Product stored proximate to the upper body section and the shoulder can be easily squeezed out toward the mouth.
In another embodiment, the upper body section and the shoulder may take a shape to release the length that changes during deformation at a position away from the steps. The upper body section and the shoulder do not warp after deformation. The upper body section and the shoulder can extend in a traverse direction such that the extended portions are absorbed by a cavity of the upper body section.
In yet another embodiment, the tubular body section and the upper body section are configured to deform to a predetermined shape. A concave crease can be disposed between the upper body section and the tubular body section. In a further embodiment, at least a portion of a lower edge of the upper body section and at least a portion of an upper edge of the tubular body section slope inward toward the crease. The tubular body section and the upper body section can fold inward toward the concave crease when the tubular body section and the upper body section are pushed inward centering on the crease.
In an embodiment, the tubular body section includes a pair of second creases that mutually face and enclose the central axis. The pair of second creases may be positioned at two upper and lower parallel edges in a substantially flat shape. In this structure, the tubular body section can be induced to deform in a substantially flat shape since the region in the tubular body section is formed because of the two flat edges. The pair of second creases may be formed in convex shape such that the tubular body section would fold outward and deform in a substantially flat shape. In this structure, the tubular body section can be induced to assume a substantially flat shape. In addition, product adhering to the inner wall of the tubular body section can be squeezed outward compared to a tubular body section that deforms by inward folding.
The main unit can include a lower body section connecting the tubular body section to the base. The lower body section may deform to a different shape or at a different rate than the tubular body section.
The cross-sectional shape of the tubular body section can take the shape of any suitable or flexible shape. In one embodiment, the shape is cylindrical. In another embodiment, the shape is rectangular. In yet another embodiment, the shape is elliptical. In another embodiment, the shape is square. In another embodiment, the shape is polygonal.
Deformation of the tubular body section into a substantially flat shape can be plastic deformation. In other words, the tubular body section does not spontaneously revert to its original shape when the transverse force is removed following deformation.
Reference will now be made in detail to various, exemplary embodiments illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts. Terms used in the specification are defined as follows:
Terms that indicate direction, such as “upper” and “lower”, are used when a plastic bottle 1 is set upright on a horizontal plane, the plane depicted in
Referring to
Mouth 2 opens at the upper edge to function as an outgoing port for a product. The aperture of mouth 2 is opened and closed by a threaded cap. (Not shown.) Lower edge 2a of mouth 2 is molded in ring shape of predetermined thickness.
As illustrated in
Main unit 3 is described with reference to
Main unit 3 is configured to deform from the state shown in
Next, creases 21, 22, and 23 are described with reference to
Creases 21 and 22 are formed in concave shape on the outer wall of main unit 3 and extend over roughly the entire circumference of main unit 3, as shown in
In addition, crease 21 has one traverse groove 33 with a frontal position shifted 90 degrees relative to crease 23, concave grooves 34, 34 continuous with both edges of traverse groove 33, and traverse grooves 35, 35 continuous with concave grooves 34, 34, as shown in
In this manner, steps (steps 31, 32, etc.) are attached to creases 21, 22, and the steps first bend so as to form a transverse cross-sectional shaped apex at creases 21, 22, followed by bending outward of the discontinuous section when external force F is applied. As a result, creases 21, 22 can bend in stages, and main unit 3 can more easily deform than a structure lacking steps. In an embodiment, crease 21 includes a plurality of step bends.
Furthermore, the application of external force F to the center of traverse groove 33 can form concave groove 34 having a different width and depth than traverse grooves 33 and 35. Continuous concave sections of creases 21, 22 are positioned on the surface of the side to which external force F is applied, while discontinuous sections of creases 21, 22 as well as convex creases 23, 23 are positioned on the surface of the side opposite from the surface to which external force F is applied. Central body section 13 can be induced to deform to a substantially flat shape due to the concave/convex spatial relationship.
Lower edge 12a of upper body section 12 and upper edge 13a of central body section 13 are slanted to the inside toward crease 21 in a lateral view as shown in
Next, shoulder 11 is described with reference to
Next, upper body section 12 is described with reference to
In the course of deformation of upper body section 12, flat section 53 collapses to the inside, and both edges of flat section 53 extend in the transverse direction, as shown in
In this manner, in comparison to the pre-deformation shape, shoulder 11 and upper-body section 12 extend in the transverse direction after deformation, and the extended portions are absorbed by cavity 42 and cavity 52. In other words, the extended portions (length) of shoulder 11 and upper body section 12 that changed are released since cavity 42 and cavity 52 are formed in shoulder 11 and upper body section 12. By so doing, no strain develops on shoulder 11 and upper body section 12 following deformation.
Turning now to lower body section 14, lower body section 14 is a cylindrical circumferential wall that extends between base 4 and crease 22, as shown in
In the course of deformation of lower body section 14, the top of first sections 61, 61 open to the outside while the top of second sections 62, 62 collapse to the inside, and the height of lower body section 14 falls, as shown in
Following deformation as shown in
Next, rigid portion 5 is described in reference to
Circumferential wall section 81 extends in the circumferential direction of main unit 3 so as to be discontinuous at two sections that mutually face and enclose the Y-Y central axis. In detail, circumferential wall section 81 comprises two arc sections 81a, 81a. The arc sections 81a, 81a have regions that mutually face and enclose the central axis at the most distant position from the Y-Y central axis in bottle 1. Specifically, the most distant sections of arc sections 81a, 81a from the Y-Y central axis form the greatest outer diameter of bottle 1.
Arc section 81a lies on the outside of the upper outer circumferential wall of main unit 3. In greater detail, it is positioned at step 90 between fan section 41 and flat section 53. The inner wall of arc section 81a makes planar contact with the outer wall of step 90. In addition, concave rib 84 is formed in the middle part of arc section 81a along the direction of extension (circumferential direction) to reinforce circumferential wall section 81.
Connecting section 82 comprises four strip shaped sections 82a, 82a, 82b, 82b that are positioned above shoulder 11. Two strip shaped sections 82a, 82a collaborate with one arc section 81a in cantilever support of arc section 81a in the planar view of
The upper plane of strip shaped sections 82a, 82a match the upper plane of fan section 41 that is arranged between them. Similarly, the upper plane of strip shaped sections 82b, 82b matches the upper plane of fan section 41 that is arranged between them. In addition, cavity 42 between strip shaped section 82a and strip shaped section 82b faces them at a position lower than them.
In the structure of rigid portion 5, when bottle 1 is stacked horizontally in an vending machine, for example, rigid portions 5, 5 of bottles 1, 1 make mutual contact. Since rigid portion 5 has high traverse strength, as indicated above, plastic deformation would be inhibited even if a load were sustained from an adjacent bottle 1. Therefore, bottles 1 that are stacked maintain their shape. In particular, external force in the transverse direction sustained by circumferential wall section 81 could be released broadly to step 90 since circumferential wall section 81 makes planar contact with step 90. On the other hand, when main unit 3 undergoes deformation, the deformation would not be obstructed by rigid portion 5. In an embodiment, step 90 can separate from rigid portion 5 in the series of deformation steps. (Not shown.)
Next, the folding of main unit 3 without bending base 4 is described with reference to
In such a spatial relationship, bottle 1 satisfies (a) to (c) below in the shape preceding deformation shown in
arc BHD=curve BGD; (a)
curve BCD=curve BFD>curve BGD; and (b)
straight line CH=straight line CG. (c)
In addition, if (d) below is satisfied in the shape preceding deformation shown in
arc AE=arc BHD (d)
Arc AE becomes a straight line, as shown in
In yet another embodiment, the shape preceding deformations disclosed herein can also be configured in upper body section 12 and shoulder 11. By so doing, upper body section 12 can be folded without bending of shoulder 11. In this case, the shape for release of the length that changes during deformation (cavity 42 and cavity 52) must be formed in upper body section 12 and shoulder 11.
When dispensed, the product can be expelled from the retention space via mouth 2 by flattening main unit 3. In particular, creases 21, 22, 23 and sections of main unit 3 connected thereto are configured to induce deformation. Moreover, main unit 3 can be folded even without folding base 4, thereby enabling substantially the entire retention space of main unit 3 to be emptied. Thus, product located proximate to upper body section 12 and shoulder 11 and proximate to lower body section 14 and base 4 can be dispensed through mouth 2 by bending upper body section 12 and lower body section 14, as denoted by arrows 72, 74, 76, and 78 in
Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.
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