The present disclosure is directed to disposable, single use and single serving beverage packages.
Coffee machines for offices, homes, and other establishments provide single serve cups of coffee. Typically, users can select from a large variety of coffee types, insert a sealed packet or pod containing the desired beverage choice, and within a minute or two enjoy a freshly brewed cup of coffee or other beverage. After use, the spent pod is thrown away.
Single serve packets come in a variety of sizes and shapes and can be referred to as pods, cups, K-Cups, packets, T-pouches, etc., depending on which coffee machine the packet was designed to fit. Typically, the package, pod or packet is made of plastic and/or aluminum foil. In order to make a good cup of coffee or other beverage, the packets have a defined interior volume that holds the ingredients, such as ground coffee, tea, or other ingredients. Depending on the nature of the contents, it may contain a filter in which case the volume will be divided in two parts: that which is above (i.e., upstream) and that which is below (i.e., downstream) of the filter.
The package is hermetically sealed to preserve the product's freshness. In operation, this seal is broken by a piercing means typically located on the brewing machine, allowing hot water and/or steam to enter the packet and intermix with the contents. A second opening in the package, which may be pierced or cut by the machine, allows the brewed product to exit the package and flow to a receiving cup. After the beverage has been brewed, the spent package is discarded.
Structurally, the package can be broken down to three elements: a top or sealing means; a filter to retain the spent product (if of a granular form such as coffee); and a base or volume defining means. Depending on the particular machine being used, the package will take on different shapes. All however, will typically contain the structural elements described above, namely, a top, filter, and a base.
Shown in
Another common package is shown in
As can be seen, all the prior art packages or pods are structurally similar. All have a top that is pierced to allow the entry of hot water and/or steam. All use a filter affixed to the volume to retain the spent ingredients (e.g., coffee grounds). All have a means for the brewed liquid to exit the space beneath the filter.
This disclosure describes a biodegradable pod or package designed to work in single serve beverage machines. The package of the present invention includes the three main components: a base, a filter, and a top. However, the package of the present invention utilizes a unique bond between the three components so as to withstand the temperature and pressures to which the pod is exposed by the beverage machine. In some embodiments, the bond is formed by melted or softened biodegradable polymeric material from the base and the filter that also adheres the top. In addition, friction force between the filter and the inside walls of the base offloads some of the force placed on the bond, further increasing the integrity of the pod. In some embodiments, the base and filter are formed from a material that includes biodegradable polymeric material, such as polylactic acid (PLA). The biodegradable polymeric material may be a sheet or film, may be a coating on a carrier material, or may be fibers forming a woven or nonwoven sheet. For example, the base and/or filter can be formed from suitable water impermeable or water permeable paper which is then treated (e.g., coated) with PLA. The top is also formed from biodegradable material. In some embodiments, the top is formed from a cellulosic material or other plant-based material and a suitable biodegradable sealing agent may be used to seal the top to the base.
A first particular embodiment of the invention is a single use beverage package comprising a base comprising biodegradable polylactic acid-containing material; a top comprising biodegradable cellulose-based material, together the base and the top defining an interior volume; a filter comprising biodegradable polylactic acid-containing material positioned in the interior volume, the filter retaining beverage ingredients; and wherein the filter and top are hermetically sealed to the base via the polylactic acid in the base and filter.
A second particular embodiment of the invention is a single use beverage package comprising a pouch having side walls and an interior volume comprising biodegradable polylactic acid-containing material; a filter comprising biodegradable polylactic acid-containing material positioned in the interior volume of the pouch, the filter retaining beverage ingredients; and wherein the filter is sealed to the sidewalls of the pouch via the polylactic acid in the base and filter.
A third particular embodiment of the invention is a method of making a single use beverage package comprising providing a base comprising biodegradable polylactic acid-containing material; providing a filter comprising biodegradable polylactic acid-containing material; providing a top comprising biodegradable cellulose-based material; and attaching the filter and top to the base with the polylactic acid in the base and filter to form a seal between the base, filter and top by applying heat and/or pressure to the base and the top.
These and various other features and advantages will be apparent from a reading of the following detailed description.
The invention may be more completely understood in consideration of the following detailed description of various embodiments of the invention in connection with the accompanying drawing, in which:
The present disclosure provides biodegradable pods or packages for single service beverage machines, such as coffee machines. Examples of such machines include those available from Keurig, Tassimo (by Bosch), and Flavia Fusion (by Mars). The packages of the present invention can be used with existing single serve coffee machines, may be hermetically sealed, they are economical to produce, and biodegradable after use. Prior to use, the package is sealed to preserve the freshness of the product present within the package. During use in a single serve brewing machine, the package is ruptured (e.g., a seal is broken) and hot water and/or steam is allowed to pass through the filter, through the beverage ingredients, out from the package and then into the cup, providing a beverage to be enjoyed. Although the following discussion uses the term “package”, it is understood that use of this term is not limiting and is intended to encompass products that may alternately be called pods, cups, packets, and the like.
In the following description, reference is made to the accompanying drawing that forms a part hereof and in which are shown by way of illustration at least one specific embodiment. The following description provides additional specific embodiments. It is to be understood that other embodiments are contemplated and may be made without departing from the scope or spirit of the present invention. The following detailed description, therefore, is not to be taken in a limiting sense. While the present invention is not so limited, an appreciation of various aspects of the invention will be gained through a discussion of the example provided below.
Unless otherwise indicated, all numbers expressing feature sizes, amounts, and physical properties are to be understood as being modified by the term “about.” Accordingly, unless indicated to the contrary, the numerical parameters set forth are approximations that can vary depending upon the desired properties sought to be obtained by those skilled in the art utilizing the teachings disclosed herein.
As used herein, the singular forms “a”, “an”, and “the” encompass embodiments having plural referents, unless the content clearly dictates otherwise. As used in this specification and the appended claims, the term “or” is generally employed in its sense including “and/or” unless the content clearly dictates otherwise.
The package of the present invention includes a base, filter, and a top cover. In accordance with the invention, the base is made from a polymeric biodegradable material or suitable material (e.g., paper or other cellulosic or biodegradable material) treated with polymeric biodegradable material. The filter is present within the interior volume of the base and retains the coffee or other beverage ingredients. The filter is made from a polymeric biodegradable material, a PLA-paper fiber mix or cellulose material (e.g., typical coffee filter material) that has been optionally coated with PLA or other sealant material at least in the seal area (i.e., the area where the seal with the cup and/or top will be made). By using biodegradable polymeric material to form the base and the filter, additional sealing materials to assemble the package are avoided. In alternative embodiments where a sealant material is used, suitable sealing agents or materials include polymeric and biodegradable adhesives and resins. For example, DuPont Surlyn® packaging adhesives and resins available from DuPont, Wilmington, Del. are suitable sealing agents for use in the present invention.
It is to be understood that although the following discussion is directed to a single serving coffee package, the package could be used for other single servicing beverages, such as tea, hot chocolate, lanes, etc. Further, use of the term “single serving” or variations thereof is intended to cover volumes of 4 to 12 fluid ounces (e.g., 4 oz, 6 oz, 8 oz, 10 oz, or 12 oz).
Referring again to the prior art package products, the various package configurations are known. For example, as seen in
Referring to
In accordance with this invention, base 9 is formed from a biodegradable film or sheet material, preferably plant-based. Examples of suitable materials include degradable polyethylene, biodegradable polyester amide, polylactic acid, starch-based polymers, cellulose derivatives and polypeptides. Polylactic acid (i.e., PLA), a biodegradable polymeric material made from corn and available from Cargill Inc., Minneapolis, Minn., is preferred for base 9. PLA is obtainable as a film or sheet material that can be readily molded and formed (e.g., vacuum formed). Alternately PLA can be obtained as a bulk material that can be applied (e.g., coated) on a carrier material, such as a paper sheet or web. Multiple base units 9 can be ganged formed as in a matrix array, or handled individually. Some versions of PLA film or sheet material include polyvinylidone chloride (PvdC) or polyglycolic acid (PGA) to improve the barrier properties and inherently have a high barrier resistance to O2. Alternatively, other treatments can be used such as egg-based coating, paraffin spray, corn- or soy-based substances or beeswax to improve barrier resistance to O2. Although base 9 is shown in
Filter 7 is positioned within base 9 and retains the coffee grounds, both before and after use of the package. Filter 7 allows water (or other liquid) to pass through the coffee and then through filter 7 while retaining the grounds. During brewing, filter 7 is the element that is subjected to the maximum amount of force against it.
In accordance with this invention, filter 7 is formed from a biodegradable polymeric material, preferably plant-based. Polylactic acid (i.e., PLA), a biodegradable material made from corn, is preferred for filter 7. Alternately filter 7 may include a coating of PLA on a suitable substrate, such as paper or cellulose.
The physical configuration of the filter media for filter 7 is an important design features. An overly restrictive filter weave would lengthen brew time, and possibly result in rupturing the filter. If the weave to too loose, the water may pass too quickly through the filter, limiting the extraction of the coffee flavor from the grounds. It has been determined that a filter material that provides a 30-32 second brew time is preferred for a single serving size. A preferred non-woven PLA filter material for filter 7 is available from Yamanaka Industry Co., Ltd, Kyoto, Japan under the designation “Soilon NW 080” (80 gsm).
As one example, filter 7 may be pre-formed by a vacuum draw means. A thin layer of resilient material, such as neoprene, facilitates the draw and serves to ease handling and packaging. As with base 9, multiple filters 7 can be arranged as a matrix (to match that of the base cups) or individually handled.
Filter 7 may be formed and then coffee provided to the filter immediately prior to assembly of the final package. Alternately, a pre-filled filter pouch may be formed and then subsequently inserted into base 9. See, for example,
Returning to
In accordance with this invention top 8 is also formed from a biodegradable material. Top 8 may be formed from PLA material, or may be formed from other suitable materials. It has been found that it is difficult to provide pure PLA with the colorful and decorative features, thus top 8 may be formed from materials other than PLA. One suitable material for top 8 is a three-layer material, having a clear substrate, graphics, and a foil-backed substrate. Biodegradable films made by Innovia Films Ltd, England, NatureFlex™ NKR and NatureFlex™ NM are sandwiched with graphics by the Revere Group (Seattle, Wash.) to produce a biodegradable product made from a tree-based cellulose that has the look and feel of contemporary package tops. This material provides the physical properties and decorative qualities for top 8 desired while being biodegradable.
The package of the present invention may include a one-way venting valve in top 8, preferably centered in top 8. Because the coffee packaged in the biodegradable packages of this invention will preferably and typically be fairly fresh, a high level of out-gassing may be experienced from the coffee. To decrease the pressure within the packaged, a valve comprising a plurality of ports in a multi-layer top 8 is provided. If the three-layer material for top 8 is that from The Revere Group, an additional sheet or layer is preferably added to the to the three-layer material in a separate operation.
The illustrated valve is formed by a plurality of ports 13 in a first or outer layer, illustrated as an annulus surrounding a central port 14 in a second or inner layer. In
During assembly, filter 7 is positioned within base 9 and a charge of freshly roasted and ground coffee is placed on filter 7, if not already present. Preferably, filter 7 snugly fits in base 9, but stops short of the closed end of base 9 (approximately ½ to ¾ of the distance between the open end of base 9 and the closed end, e.g., ⅔ of the distance). Having filter 7 stop short of the bottom of base 9 defines a “brewing volume”, allows for any stretching of filter 7 and accommodates the mechanism that pierces and/or drains brewed coffee from the package (see, for example, piercing means 5 of
Referring to
After positioning of filter 7 between base 9 and top cover 8, a sealing mechanism, such as top platen 10a and corresponding bottom platen 10b, seals the three components together and a forms a peripheral seal. The seal between the components should be continuous along the entire circumference or periphery of the top of the resulting package. Although it is preferred that a continuous seal is formed, multiple seals may be formed and connected to form the final continuous seal.
After formation of the package (as shown in
If a pre-filled filter is used, such as coffee pouch 17 from
Alternatively, a pre-filled filter may be retained within base 9 without being sealed thereto.
As seen in
The foregoing description has focused on using a biodegradable polymeric material for base 9 and filter 7. The following discussion provides various embodiments and alternate features that could be incorporated into base 9. For example, there are instances where a manufacturing process would be better suited to forming base 9 from a suitable planar material, rather than by molding.
Turning to
Σ=r+l+t (1)
To accommodate through folding the difference between the starting circumference and the ending circumference, δ, where:
δ=2π(Σ−R), (2)
and where the material is pleated in a cupcake-paper fashion to provide pleats in the side wall of the resulting base. In order to evenly divide this excess along the periphery flange or rim, approximately every 10 degrees (or 36 fold), the pleat width, Δ, can be defined by:
Δ2π(Σ−R)/36. (3)
Finally, because the pleat folds back on itself, the pleat width is halved (0.5Δ).
In
In
Returning to
When this material is folded using 36 evenly spaced pleated it provides the desired cup size with a pleat width of approx. 0.023 inch.
After the paper is preferentially creased and pleated as designed, a die set having a male and female die is used to draw the folded paper to the desired geometrical shape (see
The previous discussion has been directed to single serving, single use beverage package having a configuration generally similar to that of the Keurig K-Cup® package (shown in
For example, a package similar to the Flavia Fusion package shown in
Thus, embodiments of the DISPOSABLE BIODEGRADABLE BEVERAGE PACKAGE are disclosed. The implementations described above and other implementations are within the scope of the following claims. One skilled in the art will appreciate that the present invention can be practiced with embodiments other than those disclosed. The disclosed embodiments are presented for purposes of illustration and not limitation, and the present invention is limited only by the claims that follow.
This application claims the benefit of U.S. provisional application 61/575,326 filed Aug. 17, 2011 titled “Biodegradable Beverage Pod and Method of Making Same”, the entire disclosure of which is incorporated by reference herein.
Number | Date | Country | |
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61575326 | Aug 2011 | US |