The present invention relates generally to a polymeric closure for a package. More specifically, the present invention relates to a polymeric closure that is especially desirable for a package exposed to high-temperature applications such as pasteurization, hot-fill and retort applications.
In high-temperature applications such as retort applications, the sterilization chamber can reach and maintain temperatures in excess of 250° F. for a sufficient period of time to ensure that any potentially harmful organisms that may have entered the product are killed. At such high-temperatures, chemical bonding between polymeric surfaces may occur between the closure and the container. Strong bonding, of course, is desirable for creating a robust seal, but can be potentially problematic for a user removing the closure from the container.
In retort applications, traditional closure designs include a three piece system consisting of a contoured metal disc, a donut-shaped plastisol liner and a threaded ring. The closure is used with a container to form a package. In this three piece design, the soft plastisol liner and an exterior surface of the container do not chemically bond to each other. Because there is no chemical bonding between the plastisol liner and the container, the metal disc and the plastisol liner are easily lifted and separated from the container during removal of the closure from the container. This traditional closure design, however, is not as desirable from a cost perspective. It also not desirable from an environmental perspective of the difficulty in recycling.
It would desirable to provide a closure for a package in high-temperature applications that addresses the above-noted disadvantages.
A closure comprises a polymeric top wall portion, a polymeric annular skirt portion, a polymeric liner and a polymeric disc. The polymeric annular skirt portion depends from the polymeric top wall portion. The annular skirt portion includes an internal thread formation for mating engagement with an external thread formation of a container. The polymeric disc has an exterior surface. The polymeric disc is located between the polymeric top wall portion and the polymeric liner. The polymeric disc includes a plurality of channels formed therein. The plurality of channels assists in allowing liquid to travel on the exterior surface of the polymeric disc and between the polymeric annular skirt portion and an external finish of a container.
A package comprises a container and a closure. The container has a neck portion defining an opening. The container has an external thread formation on the neck portion. The closure is configured for fitment to the neck portion of the container for closing the opening. The closure comprises a polymeric top wall portion, a polymeric liner, a polymeric disc and a polymeric annular skirt portion. The polymeric annular skirt portion depends from the polymeric top wall portion. The polymeric annular skirt portion includes an internal thread formation for mating engagement with the external thread formation of the container. The polymeric disc has an exterior surface. The polymeric disc is located between the polymeric top wall portion and the polymeric liner. The polymeric disc includes a plurality of channels formed therein. The plurality of channels assists in allowing liquid to travel on the exterior surface of the polymeric disc and between the polymeric annular skirt portion and the external thread formation on the neck portion of the container.
A closure comprises a polymeric top wall portion, a polymeric annular skirt portion and a polymeric disc. The polymeric annular skirt portion depends from the polymeric top wall portion. The annular skirt portion includes an internal thread formation for mating engagement with an external thread formation of a container. The polymeric disc has an exterior surface. The polymeric disc is located adjacent to the polymeric top wall portion. The polymeric disc includes a plurality of channels formed therein. The plurality of channels assists in allowing liquid to travel on the exterior surface of the polymeric disc and between the polymeric annular skirt portion and an external finish of a container.
A package comprises a container and a closure. The container has a neck portion defining an opening. The container has an external thread formation on the neck portion. The closure configured for fitment to the neck portion of the container for closing the opening. The closure comprises a polymeric top wall portion, a polymeric disc and a polymeric annular skirt portion. The polymeric annular skirt portion depends from the polymeric top wall portion. The polymeric annular skirt portion includes an internal thread formation for mating engagement with the external thread formation of the container. The polymeric disc has an exterior surface. The polymeric disc is located adjacent to the polymeric top wall portion. The polymeric disc includes a plurality of channels formed therein. The plurality of channels assists in allowing liquid to travel on the exterior surface of the polymeric disc and between the polymeric annular skirt portion and the external thread formation on the neck portion of the container.
The above summary is not intended to represent each embodiment or every aspect of the present invention. Additional features and benefits of the present invention are apparent from the detailed description and figures set forth below.
Other advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which:
While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that it is not intended to limit the invention to the particular forms disclosed, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.
The polymeric closures of the present invention are especially desirable for a package exposed to high-temperature applications such as pasteurization, hot-fill and retort applications. For example, a retort application may be done at temperatures greater than 250° F. Other non-limiting examples include a hot fill (generally performed at temperatures around 185° F.) or a hot-fill with pasteurization (generally performed at temperatures around 205° F.). It is contemplated that the polymeric closures of the present invention can be used in other high-temperature applications, as well as in other applications that are not high-temperature applications. For example, the polymeric closures of the present invention may be used in other applications using discs in which the disc needs to be separated from a container. One non-limiting example of the disc being separated from a container would be a canning jar application (e.g., a Ball® mason jar).
Referring to
The polymeric disc 16 of
The polymeric annular skirt portion 18 of
The internal bead 32 of
It is contemplated that the polymeric disc and polymeric liner may maintain their position by mechanisms other than an internal bead such as an internal thread formation that includes multiple threads.
The internal prying projection assists in removing the closure from the neck portion of the container. The internal prying projection is a mechanism for breaking a sealing adhesion formed between the polymeric liner and the container after processing (e.g., high-temperature processing such as retort processing). To assist in removing the closure from a container, at least a portion of the internal prying projection is typically located above the internal thread formation (i.e., closer to the polymeric top wall portion 12).
Referring to
The internal prying projection 34 of
The internal prying projection 34 of
It is contemplated that the internal prying projection may be of other shapes and sizes. For example, the internal prying projection may be a cylindrical shape, a generally rectangular or rectangular shape. The internal prying projection may also be a generally trapezoidal or trapezoidal shape.
The closure may also include a polymeric tamper-evident feature. For example, the closure 10 includes a polymeric tamper-evident band 50 (
The closure 10 may include an oxygen-barrier material. The oxygen-barrier material may be added as a separate layer or may be integrated within a material. For example, referring to
The oxygen-barrier layer may be formed by materials that assist in preventing or inhibiting oxygen from entering the container through the closure. These materials may include, but are not limited to, ethylene vinyl alcohol (EVOH). It is contemplated that other oxygen-barrier materials may be used in the closure in the oxygen-barrier layer.
The top wall portion 12 and the annular skirt portion 18 are made of polymeric material. The top wall portion 12 and the annular skirt portion 18 are typically made of polypropylene (PP) or blends including polypropylene. It is contemplated that the top wall portion and the annular skirt portion may be made of other polymeric materials. The tamper-evident band 50, if used, is typically made of the same materials as the top wall portion 12 and the annular skirt portion 18.
The disc 16 is also made of polymeric material. Non-limiting examples of a polymeric material that may be used in forming the disc 16 include polypropylene (PP), polybutylene terephthalate (PBT) or blends thereof. It is contemplated that the disc may be made of other polymeric materials.
The liner 14 is also made of polymeric material. Non-limiting examples of a polymeric material that may be used in forming the liner 14 include thermoplastic elastomer (TPE) or blends thereof. It is contemplated that the liner may be made of other polymeric materials
The closures are typically formed by processes such as injection molding, extrusion or the combination thereof. The plurality of channels is typically formed in the polymeric disc by molding. It is contemplated that the plurality of channels may be formed by other methods.
The closures of the present invention may be used with a container 108 used to form a package 100 of
The container 108 is typically made of polymeric material. One non-limiting example of a material to be used in forming a polymeric container is polypropylene. It is contemplated that the container may be formed of other polymeric materials. The container 108 typically has an encapsulated oxygen-barrier layer or material described above.
To open the container 108 and gain access to the product therein, the closure 10 is unthreaded by turning the closure 10 with respect to the container 108. Initially during the opening process, the internal prying projection 34 first engages the ledge 42 (see
It is contemplated that other prying mechanisms may be used instead of the internal prying projection 34 discussed above. For example,
The polymeric disc 216 includes a polymeric prying projection 234 located on a bottom edge thereof (as viewed from
In another embodiment,
The weakened area 335 of the polymeric liner 314 may be used without a polymeric prying projection (such as internal prying projection 34 or polymeric prying projection 234 discussed above). The weakened area 335 is sized and shaped to assist in reducing the amount of seal adhesion between the polymeric liner 314 and the container surface. By reducing the amount of seal adhesion between the polymeric liner and the container surface, it is less likely that the polymeric liner and disc will remain adhered to the container during the removal process of the closure from the container.
One detailed example of a polymeric disc with a plurality of plurality of channels is shown in
The width W1 of the channels generally ranges from about 0.005 to about 0.1 inch and, more specifically, from about 0.02 to about 0.075 inch. The width W1 of the channel is more typically from about 0.035 to about 0.06 inch. The depth D1 of the channels generally is from about 0.005 to about 0.025 inch and, more specifically, from about 0.005 to about 0.015 inch. The length L1 of the channels generally ranges from about 0.1 to about 0.4 inch and, more specifically, from about 0.15 to about 0.25 inch. The number of channels formed in the polymeric disc can vary, but is generally from about 5 to about 50 and, more specifically, from about 12 to about 36.
Referring to
Inventive and Comparative closures were made and tested. Specifically, the Inventive closure included a polymeric top wall portion (PP), a polymeric liner (TPE), a polymeric disc (PP) and an annular skirt portion (PP) that included an internal prying projection. The configuration of the Inventive closure was substantially similar to the closure 10 of
The Inventive and Comparative closures were placed and secured onto respective retort packages. The retort packages were made of PP with an EVOH encapsulated layer therebetween. The packages were placed in a retort test chamber with a temperature of about 250° F. for about 10 minutes having a chamber pressure of 24 psi. Approximately 6 samples of each of the Inventive and Comparative closures were tested. After removal from the retort test chamber, the removal torque of the Inventive and Comparative closures were tested and determined using a Spring Torque Tester (Serial No. 100-2015MRA) distributed by SecurePak.
The results of the tested showed that the Inventive closures surprisingly had an average torque removal of 11.3 inch-pounds less than that of the Comparative closures. Additionally, the Comparative closures failed to remove the polymeric disc from the container 67% of the time (33% pass rate). The Inventive closures, on the other hand, did not fail to remove the disc from the container in any of the samples, resulting in a 100% pass rate (0% failure rate).
Number | Date | Country | |
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62438589 | Dec 2016 | US |
Number | Date | Country | |
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Parent | 15287496 | Oct 2016 | US |
Child | 15716993 | US |