This invention relates to containers, and more particularly to plastic containers capable of flexing in response to changes in internal pressure.
Plastic containers for perishable products are often filled at an elevated temperature in a process generally known as hot-filling, which includes filling the product at about 185 degrees F. and immediately sealing the container. After sealing, the contents of the container contract upon cooling, which creates a vacuum condition inside the container.
Many conventional cylindrical containers would deform or collapse under the internal vacuum conditions without some structure to prevent it. To prevent collapse, some containers have panels, referred to as “vacuum panels,” located in the panel sidewall. The vacuum panels are configured to inwardly and easily flex in response to internal vacuum such that the remainder of the container body remains cylindrical. The structure between the vacuum panels, such as vertical posts, is stiff relative to the vacuum panels. Often, the vacuum panels are located about the circumference of the body of the container and then covered by a label that wraps around the circumference to hide the vacuum panels and posts.
Other hot-fill containers have a pair of opposing vacuum panels that incorporate handgrips, which usually are not covered with a label panel to enable gripping. Rather, other portions of the container, such as the cylindrical segments between the handgrips, provide a label surface.
The vacuum panels of many bottles are generally rectangular. Often, deformation of a generally rectangular vacuum panel causes high stress areas at the corners and in the areas outside the vacuum panels near the corner.
There is a need for improved containers that are lightweight and capable of withstanding hot-filling conditions.
A container is provided that includes an enclosed base, an upper portion that extends upwardly to a finish; and a body located between the base and the upper portion. The body includes a sidewall having at least one vacuum compensation element generally having a V-shape. The element comprises a first field, a second field, and a third field. The first field is nested within the second field, and the second field is nested within the third field. The elements are closed on one of an upper end and a lower end and generally open on the other one of the upper end and the lower end.
According to another aspect, a plastic hot-fill bottle may include: an enclosed base, an upper portion that extends upwardly to a finish, and a body located between the base and the upper portion. The body includes a sidewall having at least one circumferentially spaced, vacuum compensation elements. Each one of the elements comprises a first field, a second field, and a third field. The first field is nested within the second field, the second field is nested within the third field. The elements are generally enclosed on one of an upper end and a lower end and generally open on the other one of the upper end and the lower end. The element open end smoothly merges into the container sidewall. The elements may be V-shaped.
According to another aspect, a plastic hot-fill bottle may include: an enclosed base, an upper portion that extends upwardly to neck and a finish, and a body located between the base and the upper portion. The body includes a sidewall comprising: at least two vacuum compensation elements, and at least two panels, wherein the elements and panels are disposed around the circumference of the body in an alternating manner, and wherein the vacuum compensation elements have a generally V-shape. The elements comprise: a first field, a second field, and a third field. The first field is nested within the second field, and the second field is nested within the third field. The elements are generally closed on one of an upper end and a lower end and generally open on the other one of the upper end and the lower end.
For each of the aspects or structures described above, a label panel may be provided that is spaced apart from the elements. Preferably, the container has an even number of circumferentially spaced, vacuum compensation, flared elements, which may provide enhanced support of the sidewall. Ribbed or stepped eyebrows may be located adjacent to the closed end of a field. Each field or element may include a tip, transition portions, and lateral portions that are defined by ridges. Preferably, each one of the fields forms a face that is overall flat. The container may have, for example, four elements such that the container body is approximately square in transverse cross section before and after hot-filling. The body of the container may be label-less. The panels may be concave and adorned with an ornamental feature.
The inventors have found that container shown in the figures can be made lightweight. The body of the container may optionally function as a gripping surface that is label-less the label panel provides a surface for receiving the label. The gripping surface is enhanced by the field geometry.
Container 10 is capable of being hot filled and includes an enclosed base 12, an upper portion 14, a label panel 16, and a body 18. Base 12 preferably is circular and includes a circumferential heel 20, a standing ring 22, and a reentrant portion 24. Heel 20 extends downwardly from body 18 to the circular standing ring 22. Preferably, body 18 smoothly yields to heel 20, and the present encompasses additional structure (not shown in the figures), between body 18 and heel 20. Reentrant portion 24 may be of any type. For example, reentrant portion 24 may include conventional, radial reinforcing ribs, may be rigid or configured to deform in response to internal vacuum and function with the vacuum compensation features of container 10, or may comprise other structure.
Upper portion 14 includes an upper label bumper 30, a cylindrical portion 32, a dome 34, a neck 36, and a finish 38 that includes threads 40. Upper label bumper 30 defines the boundary of label panel 16. Cylindrical portion 32 preferably is short relative to the vertical length of dome 34, which extends upwardly and inwardly to neck 36. The present invention also encompasses containers having a large mouth (not shown in the figures). Threads 40 receive corresponding threads of a closure (not shown in the figures) upon hot-filling.
As shown in
Body 18 includes a sidewall 48, the lower label bumper 50 at its upper end, and four vacuum compensation elements 54, which each includes a group of fields. The element shown in full view in
The shape of elements 54a is referred to herein as a V-shape, and the term V-shaped encompasses a closed end 70 that is pointed, a circular arc, or other curved shape having a curvature smaller or larger than that of a circular arc. The term V-shape encompasses any shape having one end that narrows relative to its midsection or generally considered to constitute a “V”, and also encompasses sides that are mutually parallel or that extend outwardly from closed end 70. The invention also encompasses elements that do not have a V-shape, according to the particular language of the claims.
As shown in the Figures, each element 54a includes or is defined by a rounded tip 80, a pair of opposing curved transition portions 82 and 84 that extend outwardly and downwardly from the tip 80, a pair of lateral portions 86 and 88 that extend generally downwardly from transition portions 82 and 84, and a pair of end portions 90 and 92 that flare outwardly from lower ends of lateral portions 86 and 88. Tip 80 and transition portions 82 and 84 define a closed end 70. The spaced apart end portions 90 and 92 define an open end 72.
Each element 54 may include a first field 56, a second field 58, and a third field 60, and a fourth field 62. Preferably, each field has a ridge separating it from adjacent fields. For example, first field 56 may have a ridge 156 that defines the perimeter of a portion of field 56 and opens to element open end 72. Second field 58 may have a ridge 158 that defines the perimeter of a portion of field 58 and that opens to element open end 72. Likewise, third field 60 may have a ridge 160 that defines the perimeter of a portion of field 60 and also opens to element open end 72. And fourth field 62 has a ridge 162 that, in the embodiment shown in the figures, defines the outer boundary of the vacuum compensation element 54.
First field 56 is fit into the open end of second field 58 and is thus nested with second field 58. Preferably, the majority of the relatively flat surface of first field 56 is located within the ridge 158 that defines second field 58. Similarly, the majority of the relatively flat surface of second field 58 is located within the ridge 160 that defines third field 60 and the majority of the relatively flat surface of third field 60 is located within the ridge 162 that defines fourth field 62. In the embodiment shown in the figures, the entire area of the flat surfaces is located within the ridge of its corresponding superior field. Preferably, the surface of each of the fields is generally flat in its as-molded state. The boundary of each of the fields has the same general shape as the boundary of the outer field (that is, of the fourth field 62 in the embodiment shown in the Figures).
Each ridge may have a configuration that is designated by reference numeral 100 and may apply to each ridge 156, 158, 160, and 162.
Before hot filling or in its as-molded state, a tip of the closed end of third field 60 (that is, the flat portion of field 60 at its longitudinal centerline C adjacent inner portion 106 of ridge 160) is recessed relative to a tip of closed end of the second field 58 (that is, the flat portion of field 58 at its longitudinal centerline C adjacent inner portion 106 of ridge 158), and a tip of the closed end of the second field 58 (that is, the flat portion of field 58 at its longitudinal centerline C adjacent inner portion 106 of ridge 158) is recessed relative to a tip of closed end of the first field 56 (that is, the flat portion of field 56 at its longitudinal centerline C adjacent inner portion 106 of ridge 156).
The degree of recess of the tips preferably is small, such that a line drawn between the recessed tips (defined above) preferably is less than about 8 degrees, more preferably less than about 4 degrees, and may be zero or inclined opposite to that shown. The radial dimension of ridges 160 and 162 is large compared to the radial dimension of ridges 156 and 158 to compensate for the inward sloping of the fields.
The present invention is not limited to particular field or ridge configurations. For example, the present invention encompasses elements having any number of fields, structure that is outside of the outermost field, variations in field and element shape, and variations in ridge cross-sectional shape, as will be understood by persons familiar with hot-fill container technology.
Sidewall 48 of body 18 includes intermediate portion 64 that is generally vertical and located between adjacent elements 54, as best shown in
Lower terminal portions 67a and 67b are located respectively below elements 54a and 54b. The shape of lower terminal portion 67a has a shape for the upwardly oriented elements 54a and another shape 67b for downwardly oriented elements 54b. The shape of lower terminal portion 67a is in part defined by the open end 72 of the element 54a and the shape of lower terminal portion 67b is in part defined by the closed end 70 of element 54b.
Sidewall 48 also includes a sidewall transition portion 68 between upper terminal portion 66 of the closed end 70 and the intermediate portions 64. Preferably, sidewall portions 64, 66, and 68 smoothly merge into on another.
The inventors theorize that the open ends of each field 56, 58, 60, and 62 provide only a small amount of resistance to inward deflection about a horizontal axis while the ridges 156, 158, 160, and 162 maintain the attractive shape of elements and diminish the tendency of kinking or unsightly depressions in response to hot filling. Further, the ridges 100 are distributed to provide support throughout elements 54.
For container 10 having an even number of elements 54, the flared ends 90 and 92 extend outwardly toward the narrow, closed ends 70 of adjacent elements. For example, the right flared end 90 of downwardly directed element 54a shown in
A second embodiment container 10a is illustrated in
Body 18a includes elements 55 that are all upwardly oriented. As shown, container 10a includes four upwardly-oriented elements 55 that are preferably evenly spaced around the sidewall 48a of the body 18a so that each element 55 is diametrically opposed by another element 55.
The shape of elements 55 is referred to herein as a V-shape, and the term V-shaped encompasses a closed end 70a that is pointed, a circular arc, or other curved shape having a curvature smaller or larger than that of a circular arc. The term V-shape encompasses any shape having one end that narrows relative to its midsection or generally considered to constitute a “V”, and also encompasses sides that are mutually parallel or that extend outwardly from closed end 70a. The invention also encompasses elements that do not have a V-shape.
Each element 55 includes or is defined by a rounded tip 80a, a pair of opposing curved transition portions 82a and 84a that extend outwardly and downwardly from the tip 80a, a pair of lateral portions 86a and 88a that extend generally downwardly from transition portions 82a and 84a, and a pair of end portions 90a and 92a. that extend from lower ends of lateral portions 86a and 88a. Tip 80a and transition portions 82a and 84a define a closed end 70a. The spaced apart end portions 90a and 92a define an open end 72a. The present invention encompasses portions 90a and 90b being outwardly flared, approximately straight extensions of laterals portions 86a and 86b, and slightly inwardly directed.
Each element 55 includes a first field 56a, a second field 58a, and a third field 60a, and a fourth field 62a, each of which is as described with respect to first embodiment 10. The present invention is not limited to particular field or ridge configurations. For example, the present invention encompasses elements having any number of fields, structure that is outside of the outermost field, variations in field and element shape, and variations in ridge cross-sectional shape, as will be understood by persons familiar with hot-fill container technology.
Body 18a also includes a pair of eyebrows 83 and 85 disposed adjacent to the curved transition portions 82a and 84a at the closed end of each element 55. The eyebrows 83 and 85 are curved segments that generally follow the contour of the curved transition portions 82 and 84.
Sidewall 48a of body 18a includes intermediate portions 164a that is generally vertical and located between adjacent elements 55. Upper terminal portions 166a are located on the sidewall 48a respectively above elements 55. The shape of upper terminal portion 166a is in part defined by the closed end 70a of the elements 55. Lower terminal portions 167a are located respectively below elements 55. The shape of lower terminal portion 167a is in part defined by the open end 72a of the element 55. Sidewall 48a also includes a sidewall transition portion 168a between upper terminal portion 166a of the closed end 70a and the intermediate portions 164a. Preferably, sidewall portions 164a, 166a, and 168a smoothly merge into on another. Eyebrows 83 and 85 are located in intermediate sidewall portion 164a and upper sidewall portion 166a.
The inventors theorize that the open ends of each field 56a, 58a, 60a, and 62a provide only a small amount of resistance to inward deflection about a horizontal axis while the their ridges maintain the attractive shape of elements and diminish the tendency of kinking or unsightly depressions in response to hot filling.
Elements 55 narrow near tips 80a, and eyebrows 83 and 85 support upper sidewall portion 166a between the upper ends of adjacent elements 55. Eyebrows 83 and 85 are preferably defined by the same ridge 100 structure as the fields 56, 58, 60, and 62 described above. Thus, eyebrows 83 and 85 may support sidewall 48a in the region that would be otherwise unreinforced and that may be prone to high stress levels, which in some configurations and under some conditions may inhibit kinking upon hot filling. Although not shown in the figures, the present invention also encompasses elements 55 that are arranged about the sidewall and oriented with their open ends upwardly.
Referring to
As shown, container 10b includes elements 154 that are all upwardly oriented and that are spaced apart around the sidewall 48b of the body 18b with panels 49b disposed between them. Container 10b preferably has two upwardly-oriented elements 154 and two panels 49b that are preferably evenly spaced around the sidewall 48b of the body 18b in an alternating arrangement. Further, the elements 154 are preferably diametrically opposed and the panels 49b are also preferably diametrically opposed. Alternatively, this embodiment may incorporate downwardly oriented elements 155 (as shown in
The panels 49b disposed between the elements 154 preferably have an inwardly concave surface as shown in
Referring to
As shown, container 10c Referring to
In operation, container 10 is capable of receiving a product at an elevated hot-fill temperature, such as approximately 185 degrees F. Preferably, container 10 is formed of a plastic having an intrinsic viscosity in the range typical for hot fill containers. Container 10 may be formed by any blow molding process, such as a two stage, stretch blow molding process with a heat setting stage. The present invention is not limited to this two stage process, but rather encompasses any process for making a container and any container that employs the general technology described herein. For example, the present invention encompasses any container having one or more vacuum compensation elements, or its equivalent, as described herein.
Upon capping during the hot-filling process, elements 54 are pulled inwardly in response to internal vacuum. Intermediate portions 64 after hot filling have an upright, straight shape to form posts.
The disclosure illustrates aspects of the present invention, which encompasses obvious variants of the disclosure as understood by persons familiar with container engineering and manufacturing.
This application claims benefit of U.S. provisional application No. 60/912,064 filed Apr. 16, 2007, which is incorporated by reference herein in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/US08/60454 | 4/16/2008 | WO | 00 | 4/22/2010 |
Number | Date | Country | |
---|---|---|---|
60912064 | Apr 2007 | US |