The present disclosure relates to containers.
In some embodiments, a container is provided. The container includes a first vacuum panel, a second vacuum panel, a third vacuum panel, a first diagonal column between the first vacuum panel and the second vacuum panel, and a second diagonal column between the second vacuum panel and the third vacuum panel. The second vacuum panel and the third vacuum panel are oriented in opposite directions. In response to a change in an internal container pressure, the container flexes at the first vacuum panel such that a surface of the first vacuum panel increases in concavity in response to an increasing pressure change.
In some embodiments, the increase in concavity comprises a first portion of the surface moving towards an interior of the container and a second portion of the surface moving towards the interior of the container by a different distance than the first portion.
In some embodiments, the first vacuum panel includes an upper surface and a lower surface, and concavities of the upper surface and the lower surface increase in response to the increasing pressure change. In some embodiments, the increase in the concavity of the upper surface is different than the increase in the concavity of the lower surface.
In some embodiments, a height of the first vacuum panel is at least one-third a total height of the container. In some embodiments, the second vacuum panel and third vacuum panel each includes a base, and a distance measured from the base of the second vacuum panel to the base of the third vacuum panel is at least one-third a total height of the container.
In some embodiments, a height of the second vacuum panel is at least one-fourth a total height of the container.
In some embodiments, the first vacuum panel has two sides that are angled with respect to a longitudinal axis of the container.
In some embodiments, the second vacuum panel and third vacuum panel each includes a base and two sides and the two sides of each vacuum panel form an acute angle.
In some embodiments, the second vacuum panel and third vacuum panel are triangular.
In some embodiments, in response to the change in the internal container pressure, the container flexes at the second vacuum panel and third vacuum panel such that the base of each panel increases in concavity in response to the increasing pressure change.
In some embodiments, the container has an initial volume, and the flexing of the container decreases the initial volume by 3%. In some embodiments, the flexing of the container decreases the initial volume by 5%.
In some embodiments, the container has an oval cross horizontal section at a position intersecting the first vacuum panel, the second vacuum panel, and the third vacuum panel.
In some embodiments, the first diagonal column and the second diagonal column intersect.
In some embodiments, a container is provided. The container includes a body portion. The body portion includes two diagonal pressure accommodation areas, two triangular areas, and at least one column between each diagonal pressure accommodation area and triangular area. Each diagonal pressure accommodation area includes a first surface, a second surface, and a third surface. The first surface, the second surface, and the third surface are vertically offset from each other. Each surface is configured to curve in towards an interior of the body in response to a change in pressure within the container.
In some embodiments, each of the diagonal pressure accommodation areas includes a grip region. In some embodiments, the grip regions include spaced-apart ribs.
In some embodiments, a container for storing a liquid filled in a hot state and then sealed is provided. The container includes a pressure accommodation panel. The pressure accommodation panel includes a top-right corner and a bottom-left corner. When the container is sealed, the pressure accommodation panel is configured to twist from an original shape such that the top right corner and the bottom left corner move towards an interior of the container. When the seal is released, the pressure accommodation panel is configured to return to its original shape.
In some embodiments, the twist is initiated by cooling of the liquid.
Drinkable fluids provided to consumers, such as juices, soft drinks, and sports drinks, may be bottled using a hot-fill process. With this process, the liquid is heated to an elevated temperature and then bottled while at that elevated temperature. Specific heating temperatures vary depending on the liquid being bottled and the type of container being used for bottling. For example, when bottling a liquid for a sports drink using a container made of PET, the liquid may be heated to a temperature of 83° C. or higher. The elevated liquid temperature sterilizes the container upon filling such that other sterilization processes are not needed. After the liquid is filled, the container is immediately capped, sealing the hot liquid inside the container. The container, along with the liquid inside, is then actively cooled before the container is labeled, packaged, and shipped to the consumer.
Despite the benefits of the hot-fill process, the cooling down of the liquid after filling may cause deformation of the container and stability issues. For example, a liquid that is heated to 83° C. may be cooled down to 24° C. for the labeling, packaging, and shipping process. The cooling of the hot liquid reduces the volume of the liquid inside the container. Because the container is sealed, the volume reduction of the liquid results in a change in the container's internal pressure such that the pressure inside the container becomes lower than the pressure surrounding the container. For example, the pressure inside the container may change such that it is 1-550 mm Hg less than the pressure surrounding the container (atmospheric pressure).
As the internal pressure in the container drops, it creates a pressure differential (vacuum) that causes stresses to the container. If left uncontrolled, these stresses may result in undesirable distortion of the container shape as the container and contents tend toward an equilibrium state. For example, the container may distort significantly from its original shape so that it is difficult to label or package the container. The distortion may also negatively impact aesthetics of the container.
Thus, there exists a need for a container that may accommodate this internal pressure change during the bottling process so the container does not drastically deform from its original shape. Additionally, the container should be able to accommodate this change in internal pressure in a way that does not interfere with the stability and usability of the container. For example, the container, in its deformed shape, should still be able to withstand forces that may be experienced during shipment. Additionally, the accommodation method should not interfere with a consumer's use of the container, such as when the consumer dispenses the liquid from the container. Also, the accommodation method may be configured such that the distortion contributes to the aesthetics of the container.
In some embodiments described herein, containers include a first vacuum panel, a second vacuum panel, and a third vacuum panel where the second vacuum panel and the third vacuum panel are oriented in opposite directions. A first diagonal column is located between the first vacuum panel and the second vacuum panel. A second diagonal column is located between the second vacuum panel and the third vacuum panel. Due to the shape of the panels and orientation of the panels and columns, the container may safely accommodate a change in the internal pressure of the container without causing uncontrollable distortion. In some embodiments, the panels and orientation of the panels and columns allow the container to twist or exhibit different radial movement along its height as it deforms. Additionally, the vacuum panels disclosed herein do not interfere with the container's usability. In some embodiments, the vacuum panels contribute to the usability of the container.
In some embodiments, and as shown in
Container 1000 may be any vessel that is suitable for storing a liquid, in which, during storage, the internal pressure of container 1000 changes. In some embodiments, container 1000 is a bottle. In some embodiments, container 1000 is made of PET (polyethylene terephthalate), but other suitable flexible and resilient materials may be used, including, but not limited to, plastics such as PEN (polyethylene naphthalate), bioplastics such as PEF (polyethylene furanoate), and other polyesters.
As shown in
Referring now to
As shown in
In some embodiments, second vacuum panel 420 is similar to third vacuum panel 421 in every way except that second vacuum panel 420 and third vacuum panel 421 are oriented in different directions. This means that second vacuum panel 420 and third vacuum panel 421 are shaped and located such that they are not similarly oriented on container 1000 (e.g., second vacuum panel 420 may be oriented 180 degrees differently with respect to third vacuum panel 421). For example, when second vacuum panel 420 and third vacuum panel 421 are triangular, second vacuum panel 420 and third vacuum panel 421 may be oriented in opposite or opposing directions such that second vacuum panel 420 points “up” towards neck portion 200 and third vacuum panel 421 points “down” towards base portion 500. This is shown in
In some embodiments and as shown in
In some embodiments, first vacuum panel 410 is angled such that it is slanted to left side of container 1000. In these embodiments, second vacuum panel 420 and third vacuum panel 421 are also oriented opposite of each other, but their orientations may be flipped. For example, base 420B of second vacuum panel 420 may be closer in distance to shoulder portion 300 than base 421B and angle 420A may be closer in distance to base portion 500 than angle 421A. In other words, second vacuum panel 420 may point “down” towards base portion 500 and third vacuum panel 421 may point “up” towards neck portion 200.
In some embodiments, container 100 includes two first vacuum panels 410, two second vacuum panels 420, and two third vacuum panels 421, arranged as described above such that one of the first vacuum panels 410 is angled such that it is slanted to the right side of container 1000 and the other of the first vacuum panels 410 is angled such that it is slanted to the left side of container 1000. In such a configuration, both first vacuum panels 410 may be radially slanted in the same direction (e.g., clockwise or counterclockwise around the periphery of container 1000).
In some embodiments, and as shown in
In some embodiments, height 410h is at least one-third the total height H of container 1000. In some embodiments height 410h is at least one-half the total height H of container 1000. In some embodiments, height 420h and height 421h, individually, are at least one-fourth the total height H of container 1000. In some embodiments, height 420h and height 421h, individually, are at least one-third the total height H of container 1000. Thus, in some embodiments, first vacuum panel 410, second vacuum panel 420, and third vacuum panel 421 are prominent features of container 1000 and account for a substantial portion of the surface area of container 1000 (e.g., greater than 15% or greater than 20%).
Body portion 400 of container 1000 may also include a first column 430A and a second column 430B. As shown in
As will be described in further detail below, this arrangement initiates and contributes to the flexing of the container 1000. However, other arrangements are also envisioned so long as the flexing of first vacuum panel 410, second vacuum panel 420, and the third vacuum panel 421 described herein may be achieved.
Container 1000 may have more than one first vacuum panel 410, more than one second vacuum panel 420, and more than one third vacuum panel 421. As shown in the figures, in some embodiments container 1000 may have two first vacuum panels 410, two second vacuum panels 420, and two third vacuum panels 421.
In embodiments with two first vacuum panels 410, two second vacuum panels 420, and two third vacuum panels 421, the six panels may be located in container 1000 circumferentially. For example, in some embodiments, the two first vacuum panels 410 are positioned diametrically opposite each other, the two second vacuum panels 420 are positioned diametrically opposite each other, and the two third vacuum panels 421 are positioned diametrically opposite each other. This is shown, for example, in
As described in more detail elsewhere herein, this arrangement also allows container 1000 and, more specifically, the horizontal cross-section of container 1000 at line A-A in
In some embodiments container 1000 may include more than two first vacuum panels 410, more than two second vacuum panels 420, and more than two third vacuum panels 421. A person of ordinary skill in the art, with the benefit of this disclosure, could determine an appropriate number of vacuum panels 410, 420, and 421 and suitable placement of each depending on bottle shape and design.
In some embodiments, and as can be seen in
Ways in which vacuum panels 410, 420, and 421 control deformation of container 1000 will now be discussed in reference to
After container 1000 is filled with hot liquid, lid 600 is placed over the neck portion 200, sealing the container from the environment. This is shown in
Line 5 represents the change of the liquid temperature over time. Line 3 represents the change in the internal container pressure over time. As shown in
At time A, the liquid is still at its elevated temperature and there has been no drop in the internal pressure of container 1000.
At time A the container 1000 is in its original shape and is un-deformed because there is no change in temperature or internal container pressure. Thus,
For example, at time B in
Times C, D, E, F, and G involve progressively cooler liquid temperatures and progressively decreased internal container pressures.
The amount of flex of bottom surface of base portion 500 is small relative to the flex experienced by body portion 400. Because the vacuum panels are designed to concentrate the stresses only to that area of container 1000, the other portions of container 1000 do not experience substantial stress or deformation. Thus, due to the vacuum panels, the change in shape of the other portions due to a change in internal container pressure, including the base portion 500, is relatively small. Thus, the deformation of container 1000 is mostly contained to body portion 400.
In some embodiments, the small deformation of other portions of container 1000 compared to the deformation of body portion 400 may be quantified by determining how much that portion has flexed in towards an interior of container 1000 compared to how much first vacuum panel 410 has flexed. For example, in some embodiments, the amount of flex (e.g., deformation displacement) experienced by bottom surface of base portion 500 after deformation is, at most, 10% of the amount of flex experienced by body portion 400 at first vacuum panel 410 after deformation. In some embodiments, the amount of flex experienced by bottom surface of base portion 500 is at most 5% of the amount of flex experienced by body portion 400 at first vacuum panel 410. In some embodiments, the amount of flex experienced by bottom surface of base portion 500 is at most 2% of the amount of flex experienced by body portion 400 at first vacuum panel 410.
In some embodiments, the deformation displacements may be compared by determining what percentage of container 1000's volume reduction is contributed to the deformation of body portion 400.
For example, when the liquid cools, its volume is reduced (e.g., by 3-5%). Thus, in some embodiments, the flexing of the body portion 400 decreases container 1000's initial volume by 3%. In some embodiments, the initial volume is decreased by 5%. In some embodiments, at least 85% of the decrease in container 1000's initial volume is due to the deformation of body portion 400. In some embodiments at least 90% of the decrease in initial container volume is because of deformation of body portion 400. In some embodiments, at least 95% of the decrease in initial container volume is due to deformation of body portion 400.
As the temperature of the liquid further cools and the internal pressure of container 1000 further drops, for example, at time C, more portions of first vacuum panel 410, second vacuum panel 420, and third vacuum panel 421 start to experience stress. While first vacuum panel 410, second vacuum panel 420, and third vacuum panel 421 all experience some amount of stress, the stress experienced by first vacuum panel 410 increases at a faster rate than the stress experienced by second vacuum panel 420 and third vacuum panel 421. Additionally, the portions of the panels that experience stress spread more quickly in first vacuum panel 410 than in second vacuum panel 420 or third vacuum panel 421. For example, a comparison between
Times D, E, F, and G involve progressively cooler liquid temperatures and progressively decreased internal container pressures.
Generally,
These figures also show that the stresses on the container 1000 during the cooling process are mostly concentrated in body portion 400. In some embodiments, greater than 50% of the stresses on the container 1000 during the cooling process are concentrated in body portion 400. In some embodiments, greater than 75% of the stresses are concentrated in body portion 400. In some embodiments, greater than 90% of the stresses are concentrated in body portion 400.
As shown in
As body portion 400 flexes, the cross-sectional shape 401A changes to 402A. This change includes a flexing of first vacuum panels 410 in towards an interior of container 1000 at line A-A and a slight flexing of second vacuum panels 420 and third vacuum panels 421 in towards an interior of container 1000. As can be seen by
As shown in
As the panels experience stress and start to flex inwards, the shape of the panels' surfaces also change in response to the stress and flex.
An increase in concavity may be seen when different portions of one horizontal cross section move in towards the interior of container 1000 by different amounts. In other words, first vacuum panel 410 does not move in towards the interior of container 1000 by the same amount along the same horizontal cross section.
For example,
Additionally, as first vacuum panel 410 flexes in towards the interior of container 1000, first vacuum panel 420 also twists. A twist may be characterized as an un-symmetrical concave shape. For example, in
A twist may also be characterized as a horizontal cross section changing shape in a different way than other horizontal cross sections, which is shown in
As shown in
Additionally, as third vacuum panel 421 experiences stress, the shapes of upper surface 4210 and lower surface 4211 also change in different ways. For example, in some embodiments, upper surface 4210 near base 421B increases in concavity as the internal pressure of container 1000 changes while lower surface 4211 does not. This may be due to the fact that is oriented in an opposite direction than second vacuum panel 420.
A comparison between the stresses on second vacuum panel 420 and deformation of the surfaces of second vacuum panel 420 show that the amount of deformation or change in shape is not proportionate to the stress that is on the surface of second vacuum panel 420.
In some embodiments, container 1000 may return to its original shape when the lid 600 is removed from neck portion 200 and the seal is released. This is due to the characteristics of the body portion 400 and vacuum panels 410, 420, and 421. Not only are vacuum panels 410, 420, and 421 easily deflectable, but they also do not retain their deflected shape. The vacuum panels, especially first vacuum panel 410, remains flexible after flexing so that it may flex outwards once container 1000 is opened. First vacuum panel 410, second vacuum panel 420, and third vacuum panel 421 may be formed of a thermoplastic polymer resin, like PET (polyethylene terephthalate). Other suitable thermoplastic resins are also envisioned, like bioplastics such as PEF (polyethylene furanoate).
In some embodiments, body portion 400 and may also be shaped to allow gripping and squeezing of the container by a consumer. For example, in some embodiments, first vacuum panel 410 may have spaced-apart ribbed portions, as seen in
The present invention has been described above with the aid of functional building blocks illustrating the implementation of specified functions and relationships thereof. The boundaries of these functional building blocks have been defined herein for the convenience of the description. Alternate boundaries can be defined so long as the specified functions and relationships thereof are appropriately performed.
The foregoing description of the specific embodiments will so fully reveal the general nature of the invention that others can, by applying knowledge within the skill of the art, readily modify and/or adapt for various applications such specific embodiments, without undue experimentation, without departing from the general concept of the present invention. Therefore, such adaptations and modifications are intended to be within the meaning and range of equivalents of the disclosed embodiments, based on the teaching and guidance presented herein. It is to be understood that the phraseology or terminology herein is for the purpose of description and not of limitation, such that the terminology or phraseology of the present specification is to be interpreted by the skilled artisan in light of the teachings and guidance.
The breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the claims and their equivalents.
Further, references herein to “some embodiments,” “one embodiment,” “an embodiment,” “an example embodiment,” or similar phrases, indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it would be within the knowledge of persons skilled in the relevant art(s) to incorporate such feature, structure, or characteristic into other embodiments whether or not explicitly mentioned or described herein.
This application is a continuation of U.S. patent application Ser. No. 15/019,806, filed Feb. 9, 2016, which is incorporated herein in its entirety by reference thereto.
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