The present invention relates to packaging beverages, and more particularly to metal beverage cans capable of being charged with an activating gas.
Metal cans for packaging beverages are usually a two-piece containers formed of a can body, which is drawn and wall ironed from a 3000 series aluminum alloy, and an end, which is formed from a 5000 series alloy and seamed onto the beverage can body. A conventional end is shown in
The vast majority of beverage can ends are “easy-open” ends that have a tab riveted to a center panel of the end and a score that ruptures in response to actuation of the tab. Actuating the tab irreversibly forms a pour opening in the end.
Alternatively, some ends include a closure that seals a pour opening to form a recloseable end. For example, Xolutions markets a resealable beverage can end that is conceptually disclosed in United States Patent Publication Number 2014/0332548. As illustrated in FIG. 2 of the 548 patent application, which is reproduced as
To actuate the closure for the first time, a user lifts the heel of fixation element 110a about a hinge between elements 110a and 110b to open vent 122 by removing pin 112 from opening 122. A user then pulls element 110a rearward to move sliding element 110b from pour opening 103 and to push closure element 120 away from pour opening 103. To reclose the closure, the user reverses the direction of sliding to return element 120 to its position under pour opening 103, typically by grasping the free end of fixation element 110a. The user then pushes down on the free end of element 110a to pivot it about its hinge until pin 112 is inserted into opening 122, thereby resealing the container by plugging vent 122.
Another example of a recloseable end is disclosed in United States Patent Publication Number US2008/0053997, which lists its assignee as Bound2B. FIG. 1a of the 997 Publication, which is reproduced in this specification as
Operating element 3 includes a vent 11, which is a through-hole from the top surface of element 3 to enable communication with the headspace of the container. A rod 12 extends from underneath operating element 3 functionally from sealing element 2 and into and through vent 11. Rod 11 is both a stopper or plug of vent 11 and an indicator of whether the device is sealed.
Some prior art beverage cans include a charging port in the base. For example, a coffee and cream beverage, marketed by La Colombe Coffee, includes a grommet in its base to receive a charge of gas. Aerosol cans are typically charged through a grommet in the bottom, which typically is a thick-walled end that is seamed onto a cylindrical can body wall. Conventional grommets, such as a Universal Grommet as supplied by Ultramotive, are flexible, elastomeric structures that use conventional gas or liquid injection equipment, as understood by persons familiar with conventional charging technology.
A recloseable beverage can end that promotes charging of an activating gas into a beverage can includes a metal beverage can end shell and a recloseable seal. The end shell has a peripheral curl and a center panel that has a pour opening therein. The recloseable closure has (i) a contact surface adapted for engagement and actuation by a user's finger and (ii) a seal. A filling port of the closure can receive the activing gas to charge the can end. Actuation of the closure via the contact surface by a user breaks the seal to create a closure open-position during which beverage is capable of flowing through the pour opening.
Preferably, the seal includes an upper sealing surface and a lower sealing surface. The upper sealing surface is opposite the lower sealing surface and forms a seal about the pour opening in the closed position. The filling port may be a through hole in the closure and the closure may include a pin that seals the through hole while the closure is in a closed-position.
In some embodiments, the pin is spaced apart from the through hole when the closure is in the open position such that the filling port is a vent aperture that vents internal pressure upon actuation of the closure from a fully closed position. And/or the filling port is a through hole in the center panel, and the filling port is covered by the closure, which in comes cases can provide tamper evidence. In any case, a fitting may be located in the filling port. Preferably, the activating gas is nitrous oxide.
According to another aspect, a beverage can end includes a beverage can shell, a pour opening and actuations means, a filling port, and a gas charging fitting. The beverage can end shell includes a peripheral curl and a center panel, and the center panel includes an aperture in the center panel. The can end shell is formed of a 5000 series aluminum alloy having a thickness of between 0.007 inches and 0.011 inches, or between 0.007 inches and 0.009 inches.
The actuation means for opening the pour opening preferable is either a conventional easy open end (of the kind that has a score and tab) or recloseable mechanism. The as charging fitting is located in the filling port and is adapted for receiving a gas charging apparatus to inject gas therethrough and then form a seal. Preferably, the pour activation means includes a score in the center panel and a tab attached to the center panel by a rivet, and the filling port is an aperture through the rivet. Alternatively, the filling port can be an aperture in the center panel at a position that is spaced apart from the rivet. The filling port can be a through hole in the closure and wherein the closure includes a pin that seals the through hole while the closure is in a closed position. The pin may be spaced apart from the through hole when the closure is in the open position such that the filling port is a vent aperture that vents internal pressure upon actuation of the closure from a fully closed position. The pin and/or through hole after initial opening can be configured to indicate tamper evidence.
A method for charging a beverage can with an activating gas begins with a metal beverage container package that includes a can body, a can end seamed on to the can body, and a recloseable closure engaged with the can end. The method includes charging an activating gas into an interior of the beverage can through a filling port formed in the can end. Preferably, the can end includes a recloseable closure and the filling port is in the recloseable closure, and the charging step includes inserting a charging apparatus in the filling port, removing the charging apparatus from the filling port after the inserting step, and sealing the filling port after the removing step.
The filling port may be in can end center panel, and the charging step may include inserting a charging apparatus in the filling port and removing the charging apparatus from the filling port after the inserting step, and then sealing the filling port after the removing step.
A first embodiment is directed to a recloseable beverage can end having a gas filling feature and capabilities. Referring to
Gas charging fitting 50a is shown in the figures as a grommet having a sleeve and upper and lower flanges. The gas charging fitting may also be an o-ring or like structure, and may be resilient such that it is forms a seal around pin 38a when pin 38a is inserted into port 22a. Fitting 50a is sized to receive a charging apparatus such that an activating gas, such as nitrous oxide for charging into beverage containing milk or cream, can be charged through the closure and into the can before sealing the can. The term “activating gas” is used to refer to a gas that interacts with the liquid beverage product for improving its taste, texture, or like property. In the preferred embodiment, the activating gas is a nitrous oxide used as an agent for interacting with the cream or milk (or like fatty constituent) of a coffee beverage. The present invention is not limited, of course, to nitrous oxide as the activating gas, but encompasses other gases, including gases later developed, for improving the product.
In operation, a charge of gas can be inserted through aperture 22a by inserting a charging apparatus (preferably conventional, not shown in the figures) into fitting 50a of aperture 22a while pin 38a is spaced apart from aperture 22a. After charging and removal of the charging apparatus, the panel 11a may be actuated in the conventional way to close the pour opening and insert pin 38a into port 22a.
Port 22a preferably is sealed by pin 38a by insertion of pin 38a into fitting 50a (as shown in
A user actuates the closure 12a for the first time after the can has already been filled with a beverage. A user lifts the heel of fixation element 32a about hinge 36a to vent the can by removing pin 38a from port 22a, and thereby enabling gas to escape from the pressurized interior of the can to the ambient atmosphere. A user then pulls element 32a rearward to move sliding element 34a from pour opening 13a and to move closure element 20a away from pour opening 13a. To reclose the closure 12a, the user reverses the direction of sliding to return element 20a to its position under pour opening 13a, typically by graphing the free end of fixation element 32a. The user then pushes down on the free end of element 32a to pivot it about its hinge until pin 38a is inserted into opening port 22a, thereby resealing the container by plugging the vent.
Rivet system 230 includes an aperture 232 and a rivet 240. As shown in schematically in
Grommet 260 as shown in the figures has a flange 262, a neck 264, and a crown 266 such that grommet 260 extends through aperture 232. In this regard, flange 262 is on the underside of the end 210 and crown 266 is on the exterior side of end 210. Grommet 260 may be employed for inserting a gas or a liquid through a filling aperture in the grommet 260, which filling aperture (not shown in the figures) may be sealed after inserting the gas or liquid the aperture. Alternatively, a grommet as described in U.S. Pat. No. 6,729,362, entitled “Sealing Grommet” (and generally known in the industry as a Scheindel Universal Grommet) or the valve disclosed in U.S. Pat. No. 4,658,979, entitled “Propellant Filling and Sealing Valve,” assigned to American Can Company (the “979 Patent” may be employed. If a Universal Grommet is employed, the flange preferably is oriented on the exterior of the can end and the crown is located on the internal side of the can end. If a valve like that of the 979 Patent is employed, the flange (that is, the “sealing portion” identified in the 979 Patent by reference numeral 18) is inside the can end and the crown (that is, the collar identified in the 979 Patent by reference numeral 24) is on the exterior of the can end. Thus, at least in the case in which conventional grommets or valves are employed, the can may be charged with gas or liquid by using conventional gassing methods and equipment.
Alternatively, a gas charging fitting 250 may be employed, as illustrated schematically in
Fitting 250 as illustrated in the figures is located within the vertical sidewall 242 of the rivet. A fitting, such as indicated by reference numeral 250′ in dashed lines in
Referring to
Operating element 303 includes a vent system 51, which includes an aperture or through-hole 311 and a gas charging fitting 50a. Aperture 311 extends through the top surface of element 303 to enable gas communication between the headspace of the container and the ambient atmosphere. In the closed position, a rod 312 extends from underneath operating element 303 from sealing element 302 and into and through aperture 311. Rod 312 is both a stopper or plug of the vent aperture 311 and an indicator of whether the device is sealed.
Gas charging fitting 50b may have the structure as described above with respect to fitting 50a and/or fitting 250. In general, fittings 50a, 50b, and/or 250 may without limitation be an o-ring, tubular sleeve, solid plug (configured for piercing by an injection apparatus or probe), or like structure that is capable of receiving a gas or liquid injection apparatus or nozzle, such as a charging apparatus, such that a gas, such as nitrous oxide for charging into beverage containing milk or cream, can be charged through the closure and into the can before sealing the can. The particular dimensions and configuration of the fitting may be chosen according to the particular parameters of the application, such as the material chosen, aperture diameter, metal or plastic thickness, internal can pressure, and the like. After filling and removal of the gas charging apparatus from the fitting 50a, 50b, and or 250, the fitting can be closed by thermally deforming it by applying heat, can be closed by filling with a filler or plug and/or by applying an adhesive.
The present invention has been described employing embodiments of ends, closures, and fittings in specific configurations. The present invention is not intended to be limited to the particular embodiments described herein, but that it is intended that present invention be given its fully scope as set out in the claims.
This claims priority to U.S. Patent Application Ser. No. 62/596,137 filed Dec. 8, 2017, the disclosure of which is hereby incorporated by reference as if set forth in its entirety herein.
Number | Date | Country | |
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62596137 | Dec 2017 | US |