The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
This invention relates to containers, and more particularly to hot fillable containers having flexible portions to absorb vacuum.
Perishable beverage and food products are often placed into containers at elevated temperatures. In a conventional hot-fill process, the liquid or flowable product is charged into a container at elevated temperatures, such as 180 to 190 degrees F., under approximately atmospheric pressure. Because a cap hermetically seals the product within the container while the product is at the hot-filling temperature, hot-fill plastic containers are subject to negative internal pressure (that is, relative to ambient pressure) upon cooling and contraction of the products and any entrapped air in the head-space.
It has been a goal of conventional hot-fill container design to form stiff cylindrical portions (in transverse cross section) that maintain a cylindrical shape upon cooling. Thus, conventional hot-fill containers include designated flexing portions—vacuum panels—that deform when subject to typical hot-fill negative internal pressures. The inward deflection of the vacuum panels tends to equalize the pressure differential between the interior and exterior of the container—that is, absorb vacuum—so as to enhance the ability of the cylindrical sections to maintain an attractive shape, to enhance the ease of labeling, or like commercial appeal. Some container designs are symmetric about a longitudinal centerline and designed with stiffeners to maintain the intended cylindrical shape while the vacuum panels deflect. For example, U.S. Pat. Nos. 5,178,289, 5,092,475, and 5,054,632 teach stiffening portions or ribs to increase hoop stiffness and eliminate bulges while integral vacuum panels collapse inwardly. U.S. Pat. No. 4,863,046 is designed to provide volumetric shrinkage of less than one percent in hot-fill applications.
Other containers include a pair of vacuum panels, each of which has an indentation or grip portion enabling the container to be gripped between a user's thumb and fingers. For example, U.S. Pat. No. 5,141,120 teaches a bottle having a hinge continuously surrounding a vacuum panel, which includes indentations for gripping. In response to cooling of the container contents, the hinge enables the entire vacuum panel to collapse inwardly. U.S. Pat. No. 5,141,121 similarly teaches a bottle having an outward bulge that inverts in response to cooling of the container contents. Each of the patents referred to herein by patent number is incorporated by reference in its entirety.
It has been observed that for some containers undergoing vacuum conditions, inward deflection of portions of the container, such as panels, causes regions circumferentially spaced apart from the panels to deflect outwardly. For example, some containers having opposing handgrips, which may tend to deflect inwardly upon vacuum conditions, have label panels that may deflect outwardly under vacuum conditions.
Also, some containers are subject to creasing. For example, edges of a flex panel may locally bulge outwardly after hot-filling, which is unattractive.
In accordance with one preferred embodiment of the present invention, there has now been provided a hot-fillable container including a neck portion, an enclosed bottom portion and a body portion disposed between the neck portion and the bottom portion. The body portion has flex panels disposed about the circumference of the body portion. The flex panels include a recessed central panel and a rim extending along a periphery of the central panel. The central panels are capable of inward deflection in response to the hot-filling process. A support structure fields is interposed between adjacent flex panels, and is also capable of inward deflection in response to the hot-filling process. The support structure field includes non-vertical ribs that abut one another along at least a portion of their length. At least some of the non-vertical ribs includes opposing ends that terminate at the rim of an adjacent flex panel.
In accordance with another preferred embodiment provided by the present invention, there has now been provided a hot-fillable container including a neck portion, an enclosed bottom portion and a body portion disposed between the neck portion and the bottom portion. The body portion includes a flex portion that has a plurality of spaced apart flex panels circumferentially disposed about the body portion and a support structure field interposed between adjacent flex panels. The support structure field includes a series of non-vertical ribs that abut one another along at least a substantial portion of their lengths so as to define non-vertical hinges that are capable of facilitating radial deflection of the support structure field.
In accordance with yet another preferred embodiment of the present invention, there has now been provided a hot-fillable container including a neck portion, an enclosed bottom portion and a body portion disposed between the neck portion and the bottom portion. The body portion includes a flex portion that has a plurality of spaced apart flex panels and ribbed regions. The maximum magnitude of radially inward deflection of a central panel of each of the flex panels is substantially equivalent to the maximum magnitude of raidally inward deflection of each of the ribbed regions in response to a pressure differential of about 5 psi between an exterior and interior of the container.
A container 10 suitable for hot-filling includes a neck portion 12, a bottom portion 18, and a body portion 22. As best shown in
Bottom portion 18 includes a heel 19 that extends downwardly from body portion 22 to a standing ring 20. A base 21, as shown in
Body portion 22 preferably includes a label portion 24 and a separate flex portion 26. Body portion 22 is essentially separated from dome 16 by a deep, circumferential groove 28 that provides hoop strength to the surrounding region. A label 17b, as partially schematically indicated in
Label portion 24 preferably has a round cross section that is interrupted only by circumferential ribs 30 that provide hoop strength to the label portion 24. Circumferential ribs 30 are not required to be as deep as groove 28, although the present invention is not limited to any particular relationship between groove 28 and ribs 30, or even to existence of such groove and ribs. Label 17b preferably, for aesthetic reasons, covers circumferential ribs 30.
Flex portion 26 preferably is disposed below label portion 24 to facilitate ease of labeling and gripping. Preferably, flex portion 26 is not covered with a label. Flex portion 26 includes plural flex panels 34 and support structure fields 36. Preferably, container 10 has at least three flex panels (as shown in the figures) although the present invention encompasses employing any number of flex panels according the particular parameters of the application (such as bottle diameter, wall thickness, hot-filling conditions, desired vacuum absorption, and the like).
Each flex panel 34 includes a rim 40, a central panel 42, and a recess sidewall 44. Rim 40 preferably comprises a pair of opposing lateral rims 46a and 46b, a top rim 48a, and a bottom rim 48b. Preferably, rim components 46a, 46b, 48a, and 48b are continuous, and formed by a thin, uniform strip or border.
Recess sidewall 44 preferably comprises a pair of opposing lateral recess walls 50a and 50b that extend from opposing edges of central panel 42 to lateral rims 46a and 46b, respectively. Similarly, a top recess wall 52a and a bottom recess wall 52b extend between top and bottom edges of central panel 42 to top rim 48a and bottom rim 48b, respectively.
Central panel 42 preferably is substantially flat in its as-molded state, and has rounded corners. Accordingly, rim 40 and recess sidewall 44 have rounded corners to essentially match the outline of central panel 42. Preferably, the plane of central panel 42 is parallel to the longitudinal axis of container 10. Such orientation, while not essential, enables lateral recess walls 50a and 50b to be approximately uniform in radial dimension, which may enhance the reinforcing function of recess sidewall 44.
Support structure field 36 preferably spans between rims 40 of adjacent flex panels 34, and includes non-vertical supports, such as flex area ribs 56. As shown in the figures, ribs 56 may be formed by multiple concave (as viewed from inside container 10) outer portions 58, each of which has an upper and lower inwardly directed end 60. An end 60 of one rib 56 joins an end 60 of an adjacent rib 56 at a ridge 62.
Preferably, at least some of the circumferential ends of flex area ribs 56 are disposed proximate to or in contact with lateral rims 46a, 46b of flex panel 34. Such configuration may support lateral rims 46a, 46b and may prevent deformation of rims 46a, 46b under vacuum conditions, and may also inhibit creasing. Such configuration is not essential—rather, the present invention encompasses any configuration set forth in the claims.
Flex ribs 56 are illustrated in the figures as a series of concave portions 58. The invention is not limited to such configuration of ribs, but rather encompasses any non-vertical structure, such as ribs that are oriented other than horizontally. For example,
The flex ribs shown in the figures are not vertical, or, where the ribs are not rectilinear, the longitudinal center line or best fit line through the planar projection of the rib is not vertical. The non-vertical structure of the ribs and spaces between ribs enhance the ability of the support structure field to bend relative to a horizontal axis even while such ribs will enhance hoop stiffness of the support structure field 36, 37a, 37b, 37c, or 37d. In this regard, the ribs of support structure field 36, 37a, 37b, 37c, or 37d stiffen such support structure field from flexing in a horizontal plane or about a vertical axis.
Central panels 42 of the flex panels 34 deform inwardly, as expected. As best shown in
The functional aspects of container 10 are further illustrated in
Stresses were calculated based on a 5 psi vacuum. The temperature variation under vacuum performance was ignored. The wall thickness of container 10 was assumed to be 0.015 inches uniform throughout container 10, except the neck and base 21, which were presumed to be 0.050 inches thick. As best shown in
As best shown in
Accordingly, because the support structure field 36 undergoes inward deflection in addition to the inward deflection of the center panel 42 of flex panel 34, vacuum absorption is enhanced. The label panel portion is stiffened by ribs 30, and generally retains its circular shape to enhance labeling and appearance.
The present invention is illustrated with respect to a preferred embodiment, and the present invention is not limited to the particular structure described in the preferred embodiment of container 10. For example, the present invention encompasses a container in which a label panel (such as label portion 24 of container body 22) undergoes some deformation under vacuum conditions, becomes out-of-round under vacuum conditions, and/or is not circular in its as-molded state—even though such structure or function is not shown in the figures.
Furthermore, it is not essential that the container have separate flex portions 26 and label portions 24. For example, the present invention encompasses the body portion 22 of container 10 or (other body configuration of other container covered by the appended claims) being covered by a label (such configuration not shown in the figures). The non-mechanical and subjectively attractive appearance of body portion 22 renders it suitable for use without a label, and the flex panels 34 disposed about the circumference of container 10 enhance gripping, but such advantages are optional.
It is understood that persons familiar with hot-fill container technology will recognize additional advantages and features that flow from the present disclosure, and the present invention encompasses such additional advantages and features such that the scope of the invention is limited only by the claims.
This application claims the benefit of U.S. Provisional Application No. 60/558,790, which was filed on Apr. 1, 2004 and is incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
60558790 | Apr 2004 | US |