Patent Grant
11235920
Embodiments of the present invention provide beverage ingredient pods that can contain and be used to dispense multiple ingredients into conventional beverage bottles. They allow a user to create their own beverage at the point of use, and in doing so reduce waste and cost associated with production and delivery of pre-mixed bottled beverages. The pods include internal contained mechanisms for dispensing their contents.
For example, embodiments include a beverage ingredient pod for releasing beverage ingredients into a bottle where the pod includes a rigid cup defining a liquid-ingredient chamber, a frangible pouch defining a solid-ingredient chamber, a flexible dispensing funnel disposed around the frangible pouch, and a rigid piercer disposed at an opening of the flexible dispensing funnel. The frangible pouch is disposed across and seals an opening of the rigid cup, sealing the liquid-ingredient chamber. The rigid piercer extends to a point toward the frangible pouch so that when a force is applied to the cup while the opening of the dispensing funnel is held stationary (e.g., against a bottle opening), the flexible dispensing funnel collapses, causing the piercer to pierce through the frangible pouch and into the liquid-ingredient chamber. This releases contents of both the liquid-ingredient chamber and the solid-ingredient chamber through the opening of the flexible dispensing funnel. The contents mix with a liquid in the bottle to create a mixed beverage.
Embodiments also include a beverage ingredient pod for releasing beverage ingredients into a bottle where the pod includes a rigid cup defining a liquid-ingredient chamber, a collapsible chamber defining a solid-ingredient chamber and an exterior actuation surface, a separation membrane, a dispensing membrane, and a rigid piercer disposed within the solid-ingredient chamber. The separation membrane is disposed across and seals a first end of the rigid cup, separating the liquid-ingredient chamber and the solid-ingredient chamber. The dispensing membrane is disposed across and seals an opening at a second end of the rigid cup, sealing the liquid-ingredient chamber. The rigid piercer extends to a point toward the separation membrane, so that when a force is applied to the exterior actuation surface while the rigid cup is held stationary (e.g., against a bottle opening), the collapsible chamber collapses, causing the piercer to pierce through the separation membrane, releasing the contents of the solid-ingredient chamber into the liquid-ingredient chamber. The collapse of the collapsible chamber increases pressure within the rigid cup, which breaks the dispensing membrane, releasing the contents of both the liquid-ingredient chamber and the solid-ingredient chamber through the opening of the rigid cup. The contents mix with a liquid in the bottle to create a mixed beverage.
Embodiments also include a beverage ingredient pod for releasing beverage ingredients into a bottle where the pod includes a liquid-ingredient chamber, a solid-ingredient chamber, a frangible membrane, and a rigid piercer. The liquid-ingredient chamber is disposed adjacent to the solid-ingredient chamber. The frangible membrane is disposed between the liquid-ingredient chamber and the solid-ingredient chamber, separating the two chambers. The rigid piercer extends to a point toward the frangible membrane, so that when a force is applied to an exterior of the beverage ingredient pod while a portion of the beverage ingredient pod is held stationary (e.g., against a bottle opening), a portion of the beverage ingredient pod collapses. This causes the piercer to pierce through the frangible membrane, thereby mixing the contents of the liquid-ingredient chamber and the solid-ingredient chamber and releasing the mixed contents into the bottle. The contents mix with a liquid in the bottle to create a mixed beverage.
The accompanying drawings, which are incorporated herein and form part of the specification, illustrate embodiments of the present invention and, together with the description, further serve to explain the principles of the invention and to enable a person skilled in the relevant art(s) to make and use the invention.
The present invention(s) will now be described in detail with reference to embodiments thereof as illustrated in the accompanying drawings. References to “one embodiment,” “an embodiment,” “an exemplary embodiment,” etc., 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 is submitted that it is within the knowledge of one skilled in the art to affect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.
Pre-made beverages have long been distributed to consumers in various forms of packaging, often in plastic bottles. A significant proportion of such bottled pre-made beverages' weight and volume is often attributable to water, as a constituent part of the beverage. Significant proportions of production, shipping, storage, and other manufacturing and distribution costs are often derived from this volume and weight due to water content of a pre-made beverage.
Further, the disposal of the bottle containing the pre-made beverage after the beverage is consumed often involves recycling or other waste management processes applied to the bottle. The cost and complexity of such processes are often proportional to the volume of material forming the bottle.
Beverage ingredient pods as described herein may contain ingredients, such as concentrated flavorings, and may be used to create custom beverage mixtures by dispensing their contents into a bottle containing a liquid, such as water, juice, milk, or seltzer. Such pods may be smaller than conventional bottles, requiring less material and reducing potential manufacturing, distribution, and disposal complexity and cost. Further, such pods may allow users to create fresh beverage mixtures at the time of consumption, rather than consuming ingredients mixed at the time of beverage production. Allowing a consumer to participate in the creation of a new beverage may enhance consumer experience with an added perception of freshness.
Beverage ingredient pods according to embodiments of the invention may be used, for example, with a bottle that previously stored a pre-made beverage that has already been consumed. Such beverage ingredient pods may also be used with a purpose-built bottle configured to accept the pod and facilitate dispensing of the pod's contents. A single pod may be used with either bottle type, or with other bottles, as will be evident from the following description. Embodiments of the present invention provide flexibility to a consumer in creating a beverage at least by providing pods that include multiple separate ingredient chambers for storing ingredients (for example dry and liquid ingredients) separately that may be dispensed simultaneously into any conventional bottle in an easy and efficient manner.
To use beverage ingredient pods in accordance with some embodiments of the invention, a dispensing end of the beverage ingredient pod may be placed in the opening of a bottle containing a liquid. The user then presses down on the pod, which presses the pod against the opening of the bottle and collapses a portion of the pod. This collapse causes the beverage ingredients contained within the pod (flavorings and/or sweeteners, for example) to be dispensed from the pod into the bottle, creating a new, freshly mixed beverage for the consumer to enjoy. The collapse of the pod may cause the dispensing by driving an internal piercer of the pod through its internal chambers, or by creating a buildup of pressure within the pod that breaks open a membrane sealing its internal chambers.
Embodiments of the invention will now be described in more detail with reference to the figures.
As shown in
Rigid cup 240 may define a liquid-ingredient chamber 242 for containing a liquid beverage ingredient 220 (such as a flavoring, concentrated flavoring, syrup, or other fluid beverage additive) that may be dispensed from dispensing end 210 into bottle 10 to form a beverage mixture 18, as shown in
Frangible pouch 250 may define a solid-ingredient chamber 252, and may be disposed across an opening 244 in rigid cup 240, sealing opening 244 (and thereby sealing liquid-ingredient chamber 242). In some embodiments, opening 244 may be circular and have a diameter of approximately 40-65 millimeters. Solid-ingredient chamber 252 may contain a solid beverage ingredient 230 (such as, for example, a granulated sweetener, sugar, or other solid beverage additive) that may be dispensed from dispensing end 210 into bottle 10 to form a beverage mixture 18, as shown in
Flexible dispensing funnel 260 may be disposed around frangible pouch 250, and may share an annular rim 280 with rigid cup 240 and frangible pouch 250, such that rigid cup 240, frangible pouch 250, and flexible dispensing funnel 260 are sealed and fixed together along shared annular rim 280. Shared annular rim 280 may form, for example, an interface between rigid cup 240 and flexible dispensing funnel 260. In some embodiments, annular rim 280 may have an outer diameter of approximately 50-70 millimeters. Flexible funnel 260 may have a variety of shapes not limited to what is shown in the figures. Flexible funnel 260 may be cylindrical or frustoconical, for example. As described in more detail below, flexible funnel 260 may have a series of annular edges 264 that control the collapse of flexible funnel 260 in a dispensing operation.
Rigid piercer 270 may be fixed at an opening 262 (see
In some embodiments, piercing portion 273 (see
Rigid piercer 270 may be positioned at dispensing end 210 of pod 200 and have a dispensing opening 274 (e.g., a beverage ingredient outlet with a circular cross-section) (see
As shown, for example, in
As shown in
After liquid-ingredient chamber 242 has been pierced, liquid ingredients 220 are first drawn by gravity through solid-ingredient chamber 252, then through funnel 260 and dispensing opening 274, and finally into bottle 10. Solid ingredients 230 not dispensed by, the force of gravity may be washed out by liquid ingredients 220 as they pass through solid-ingredient chamber 252. In this way, liquid ingredients 220 and solid ingredients 230 may begin to mix even before they exit beverage ingredient pod 200. After they exit, liquid ingredients 220 and solid ingredients 230 mix with liquid 14 within bottle 10 (see
In some embodiments, a removable seal is disposed over dispensing opening 274 to seal interior airspace of flexible dispensing funnel 260 until beverage ingredient pod 200 is to be used. A user may peel off or otherwise remove the removable seal before initiating beverage creation.
In some embodiments, a temporary seal may be formed between a seating surface 276 and bottle opening 12 (e.g., due to the application of force 510), such that bottle 10 and beverage ingredient pod 200, when held together by a user, can be shaken or otherwise moved without spilling liquid in order to further mix the ingredients that have been dispensed from the pod with the liquid in the bottle, and to rinse remaining ingredients out of beverage ingredient pod 200 and into the resulting beverage mixture 18.
Rigid cup 340 may define a liquid-ingredient chamber 342 for containing a liquid beverage ingredient 320 (such as a flavoring, concentrated flavoring, syrup, or other fluid beverage additive) that may be dispensed from dispensing end 310 into bottle 10 to form a beverage mixture 20, as shown in
Collapsible chamber 350 may define a solid-ingredient chamber 352 for containing a solid beverage ingredient 330 (such as, for example, a granulated sweetener, sugar, or other solid beverage additive) that may be dispensed from dispensing end 310 into bottle 10 to form a beverage mixture 20, as shown in
Separating membrane 390 may be disposed across an opening 345 at first end 344 of rigid cup 340, sealing first end 344 (and thereby separating liquid-ingredient chamber 342 and solid-ingredient chamber 352). In some embodiments, opening 345 may be circular and have a diameter of approximately 25-55 millimeters. In some embodiments, beverage ingredient pod 300 may include three or more solid and/or liquid-ingredient chambers 342, 352 that are separated by two or more separating membranes 390 that may be pierced by rigid piercer 370 during a dispensing operation.
Dispensing membrane 395 may be disposed across an opening 347 at a second end and base 346 of rigid cup 340, sealing second end and base 346 of rigid cup 340. In some embodiments, opening 347 may be circular and have a diameter less than an outer diameter of second end and base 346 of rigid cup 340. For example, the diameter of opening 347 may be approximately 10-40 millimeters. Dispensing membrane 395 may be sealed to an internal bottom surface of rigid cup 340, as shown, for example, in
Funnel 360 may be disposed at the second end and base 346 of rigid cup 340. In this position dispensing membrane 395 separates funnel 360 from liquid-ingredient chamber 342. Funnel 360 may have a variety of shapes not limited to what is shown in the figures. As shown in
Dispensing end 369 of funnel 360 may have a dispensing opening 362 (e.g., a beverage ingredient outlet with a circular cross-section), whereby ingredients may be dispensed from beverage ingredient pod 300 into bottle 10. In some embodiments, a filter 364 is disposed within or at an end of funnel 360. Filter 364 may be, for example, a mesh screen, and beverage ingredients 320, 330 may pass through filter 364 before being dispensed from beverage ingredient pod 300.
Rigid piercer 370 may be disposed within solid-ingredient chamber 352, as shown, for example, in
In some embodiments, piercing portion 373 (see
As shown in
After separating membrane 390 has been pierced, the collapse of collapsible chamber 350 causes an increase in pressure in rigid cup 340. The pressure increase is transmitted by liquid ingredient 320 to the surface of dispensing membrane 395, thereby causing dispensing membrane 395 (or its seal with rigid cup 340) to break as a result of the pressure increase, releasing the contents of both the liquid and solid ingredient chambers 342, 352 into and through funnel 360. Dispensing membrane 395 may be sufficiently fragile or otherwise biased to break or partially separate from rigid cup 340 under pressure so that the pressure increase from the collapse of collapsible chamber 350 will cause dispensing membrane 395 to break or partially separate from rigid cup 340 without the physical contribution of any implement (e.g. the rigid piercer 370) coming into contact with dispensing membrane 395. Rigid cup 340 may have sufficient rigidity to maintain its shape through the application of force 510 that causes collapsible chamber 350 to collapse and to withstand the pressure increase caused by the collapse of collapsible chamber 350. In some embodiments, the magnitude of axial force 510 that is necessary to dispense the ingredients from beverage ingredient pod 300 into bottle 10 may be less than 30 kilograms-force.
After separating membrane 390 has been pierced, solid ingredients 320 are first drawn by gravity, or pushed by the exterior wall 354 of collapsible chamber 350, into liquid-ingredient chamber 342. In this way, liquid ingredients 320 and solid ingredients 330 may begin to mix even before they exit beverage ingredient pod 300. After dispensing membrane 395 (or its seal with rigid cup 340) has been broken, the solid and liquid ingredients 320, 330 may pass through the funnel 360 and dispensing opening 362, and finally into bottle 10 to mix with liquid 14 within bottle 10 (see
In some embodiments, a removable seal is disposed over dispensing opening 362 to seal interior airspace of funnel 360 until beverage ingredient pod 300 is to be used. A user may peel off or otherwise remove the removable seal before initiating beverage creation.
In some embodiments, a temporary seal may be formed between exterior surface 366 of funnel 360 and bottle opening 12 (e.g., due to the application of force 510), such that bottle 10 and beverage ingredient pod 300, when held together by a user, can be shaken or otherwise moved without spilling liquid in order to further mix the ingredients that have been dispensed from the pod with the liquid in the bottle, and to rinse remaining ingredients out of beverage ingredient pod 300 and into the resulting beverage mixture 20.
While embodiments of the present invention may be used to dispense ingredients into any conventional bottle in an easy and efficient manner as described above, the beverage ingredient pods may also have the versatility to be used in purpose-built bottles or in other purpose-built dispensing equipment, such as an automatic drink dispenser. A purpose-built bottle may fully or partially enclose a pod and may contain internal structure to receive and support a pod and to apply a force to the pod, thereby causing the pod to dispense its contents into the purpose-built bottle in a dispensing operation. The pod may or may not then remain in the purpose-built bottle while the beverage mixture is being consumed. Similarly, a purpose-built dispenser may fully or partially enclose a pod and may include structure to receive and support a pod and to apply a force (automatically, or through direct or indirect input from a user) to the pod, thereby causing the pod to dispense its contents in a dispensing operation.
As shown in
As shown in
It is to be appreciated that the Detailed Description section, and not the Summary and Abstract sections, is intended to be used to interpret the claims. The Summary and Abstract sections may set forth one or more but not all exemplary embodiments of the present invention as contemplated by the inventor(s), and thus, are not intended to limit the present invention and the appended claims in any way.
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.
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